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Subdivided Module Cataloguefor the Subject
Nanostructure Technologyas a Master’s with 1 major
with the degree "Master of Science"
(120 ECTS credits)
Examination regulations version: 2011Responsible: Faculty of Physics and Astronomy
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Course of Studies - Contents and ObjectivesThe Master of Science program prepares students for scientific work in the field of NanostructureTechnology. Graduates of the program are qualified to pursue doctoral studies. The objective of thestudy program is to convey to the student an in-depth understanding of physical and technologicalprinciples relevant to the fields of applied physics and nanoscience. The program aims to develop notonly physics knowledge, but also analytical thinking and problem solving skills, preparing the student forthe constantly evolving fields in which physicists and technologists typically work. The granted degree isinternationally comparable to a Masters degree in applied physics or nanotechnology.
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 2 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Abbreviations used
Course types: E = field trip, K = colloquium, O = conversatorium, P = placement/lab course, R = pro-ject, S = seminar, T = tutorial, Ü = exercise, V = lecture
Term: SS = summer semester, WS = winter semester
Methods of grading: NUM = numerical grade, B/NB = (not) successfully completed
Regulations: (L)ASPO = general academic and examination regulations (for teaching-degree program-mes), FSB = subject-specific provisions, SFB = list of modules
Other: A = thesis, LV = course(s), PL = assessment(s), TN = participants, VL = prerequisite(s)
Conventions
Unless otherwise stated, courses and assessments will be held in German, assessments will be offeredevery semester and modules are not creditable for bonus.
Notes
Should there be the option to choose between several methods of assessment, the lecturer will agreewith the module coordinator on the method of assessment to be used in the current semester by twoweeks after the start of the course at the latest and will communicate this in the customary manner.
Should the module comprise more than one graded assessment, all assessments will be equallyweighted, unless otherwise stated below.
Should the assessment comprise several individual assessments, successful completion of the modulewill require successful completion of all individual assessments.
In accordance with
the general regulations governing the degree subject described in this module catalogue:
ASPO2009
associated official publications (FSB (subject-specific provisions)/SFB (list of modules)):
29-Jun-2011 (2011-48) except for mandatory electives added in Fast Track procedure at alater time
2-Sep-2014 (2014-50) except for mandatory electives added in Fast Track procedure at alater time
17-Dec-2014 (2014-86)
This module handbook seeks to render, as accurately as possible, the data that is of statutory relevan-ce according to the examination regulations of the degree subject. However, only the FSB (subject-spe-cific provisions) and SFB (list of modules) in their officially published versions shall be legally binding.In the case of doubt, the provisions on, in particular, module assessments specified in the FSB/SFBshall prevail.Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
The subject is divided into
Abbreviation Module titleECTS
credits
Method of
gradingpage
Compulsory Courses (44 ECTS credits)
11-FS-N-072-m01 Professional Specialization Nanostructure Technology 15 NUM 9
11-MP-N-072-m01Scientific Methods and Project Management Nanostructure
Technology15 NUM 10
11-PFM-111-m01 Advanced Practical Course Master 10 B/NB 98
11-OSN-111-m01 Advanced Seminar Nanostructure Technology 4 NUM 107
Compulsory Electives (46 ECTS credits)
Specialization in Nanostructure Technology (40 ECTS credits)Modules worth a total of 40 ECTS credits must be successfully completed. Of these 40 ECTS credits, no less than 10 mustbe achieved in one of the two sub-areas "Elektronik und Photonik" ("Electronics and Photonics") and "Energie- und Materi-alforschung" ("Energy and Materials Research"). No less than 10 ECTS credits must be achieved in the sub-area "AllgemeinePhysik" ("General Physics"). The remaining 20 ECTS credits may be achieved in any of the sub areas.
Electronics and Photonics
11-FPA-112-m01 Visiting Research Project 10 NUM 129
11-EXN6A-112-m01 Current Topics in Nanostructure Technology 6 NUM 132
11-HLF-092-m01 Semiconductor Lasers - Principles and Current Research 6 NUM 49
11-HNS-092-m01 Semiconductor Nanostructures 6 NUM 57
11-NAN-092-m01 Nanoanalytics 6 NUM 59
11-NOP-092-m01 Nano-Optics 4 NUM 63
11-SPD-102-m01 Semiconductor Physics and Devices 6 NUM 89
11-QTH-102-m01 Quantum Transport in Semiconductor Nanostructures 6 NUM 91
11-SPI-102-m01 Spintronics 6 NUM 94
11-EXN5-111-m01 Current Topics in Nanostructure Technology 5 NUM 108
11-EXN6-111-m01 Current Topics in Nanostructure Technology 6 NUM 109
11-EXN7-111-m01 Current Topics in Nanostructure Technology 7 NUM 110
11-EXN8-111-m01 Current Topics in Nanostructure Technology 8 NUM 111
11-DFT-142-m01Densitiy Functional Theory and the Physics of Oxide Hete-
rostructure4 NUM 149
Energy Research and Material Science
08-SAM-092-m01Technology of Sensor and Actor Materials including Smart
Fluids5 NUM 32
11-OHL-092-m01 Organic Semiconductor 5 NUM 33
08-EEW-101-m01 Electrochemical Energy Storage and Conversion 5 NUM 37
11-FPA-112-m01 Visiting Research Project 10 NUM 129
11-EXN6A-112-m01 Current Topics in Nanostructure Technology 6 NUM 132
11-ENT-092-m01 Principles of Energy Technologies 6 NUM 46
11-TDO-092-m01 Thermodynamics and Economics 6 NUM 51
11-NTE-092-m01 Nanotechnology in Energy Research 4 NUM 95
11-BVG-092-m01 Coating Technologies based on Vapour Deposition 5 NUM 97
08-PCM4-PHY-111-m01 Ultrafast Spectroscopy and Quantum Control 5 NUM 105
08-MW-PHY-111-m01Structure and Properties of Modern Materials: Experiments
and Simulations5 NUM 106
11-EXN5-111-m01 Current Topics in Nanostructure Technology 5 NUM 108
11-EXN6-111-m01 Current Topics in Nanostructure Technology 6 NUM 109
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
11-EXN7-111-m01 Current Topics in Nanostructure Technology 7 NUM 110
11-EXN8-111-m01 Current Topics in Nanostructure Technology 8 NUM 111
11-ZDR-111-m01 Principles of two- and threedimensional Röntgen imaging 6 NUM 125
11-TDOE-141-m01 Thermodynamics and Economics 3 B/NB 148
11-ZMB-112-m01Methods for non-destructive Characterization of Materials and
Components4 NUM 134
11-BSV-122-m01 Image and Signal Processing in Physics 6 NUM 135
11-BMS-121-m01 Imaging Methods at the Synchrotron 4 NUM 136
11-BMS-131-m01 Imaging Methods at the Synchrotron 4 NUM 141
11-BSV-131-m01 Image and Signal Processing in Physics 6 NUM 142
11-PMM-132-m01 Physics of Advanced Materials 6 NUM 145
11-QUI-132-m01 Quantum Information Technology 6 NUM 147
General Physics
11-FPA-112-m01 Visiting Research Project 10 NUM 129
11-EXP6A-112-m01 Current Topics of Physics 6 NUM 133
11-ASL-092-m01 Applied Superconduction 6 NUM 45
11-EPP-092-m01 Introduction to Plasmaphysics 6 NUM 48
11-FK2-092-m01 Solid State Physics 2 8 NUM 53
11-FKS-092-m01 Solid State Spectroscopy 6 NUM 55
11-HLP-092-m01 Semiconductor Physics 6 NUM 56
11-MAG-092-m01 Magnetism 6 NUM 58
11-NDS-092-m01 Low-Dimensional Structures 4 NUM 61
11-QM2-092-m01 Quantum Mechanics II 8 NUM 64
11-QPM-092-m01 Quantum Phenomena in electronic correlelated Materials 6 NUM 66
11-QVTP-092-m01 Many Body Quantum Theory 8 NUM 67
11-RMS-092-m01 Relativistic Effects in Mesoscopic Systems 5 NUM 69
11-TFK-092-m01 Theoretical Solid State Physics 8 NUM 70
11-TSL-092-m01 Theory of Superconduction 5 NUM 72
11-BMT-092-m01 Biophysical Measurement Technology in Medical Science 6 NUM 73
11-LMB-092-m01 Laboratory and Measurement Technology in Biophysics 6 NUM 74
11-PKS-092-m01 Physics of Complex Systems 6 NUM 75
11-QIC-092-m01 Quantum Information and Quantum Computing 5 NUM 76
11-SDC-092-m01 Statistics, Data Analysis and Computer Physics 4 NUM 78
11-A2-092-m01 Electronics 6 NUM 88
11-RMFT-102-m01 Renormalization Group Methods in Field Theory 6 NUM 92
11-MSS-102-m01 Methods in Surface Spectroscopy 4 NUM 100
11-EXE6-111-m01 Current Topics in Experimental Physics 6 NUM 101
11-EEW-102-m01 Electron Electron Interaction 4 NUM 102
11-TFK2-111-m01 Theoretical Solid State Physics 2 8 NUM 103
11-EXT6-111-m01 Current Topics in Theoretical Physics 6 NUM 104
11-EXP5-111-m01 Current Topics in Physics 5 NUM 112
11-EXP6-111-m01 Current Topics in Physics 6 NUM 113
11-EXP7-111-m01 Current Topics in Physics 7 NUM 114
11-EXP8-111-m01 Current Topics in Physics 8 NUM 115
11-IEM-111-m01 Introduction to Electron Microscopy 4 NUM 126
11-FTFK-112-m01 Field Theory in Solid State Physics 8 NUM 128
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
11-CMS-122-m01 Computational Materials Science 8 NUM 137
11-CMS-131-m01 Computational Materials Science 8 NUM 139
11-ASL-131-m01 Applied Superconduction 6 NUM 143
11-FKS2-132-m01 Solid State Spectroscopy 2 6 NUM 144
11-TFP-132-m01 Topology in Solid State Physics 6 NUM 146
Non-technical Subsidiary Subjects (6 ECTS credits)
Mathematics
10-M-ORS-072-m01 Operations Research 5 NUM 8
10-M-NM1-082-m01 Numerical Mathematics 1 8 NUM 29
10-M-NM2-082-m01 Numerical Mathematics 2 5 NUM 30
10-M-VAN-082-m01 Advanced Analysis 8 NUM 31
10-M=AAAN-102-m01 Applied Analysis 10 NUM 83
10-M=AFTH-102-m01 Complex Analysis 10 NUM 84
10-M=VGDS-102-m01 Groups and their Representations 10 NUM 85
10-M=VNPE-102-m01 Numeric of Partial Differential Equations 10 NUM 86
10-M=VQKC-102-m01 Quantum Control and Quantum Computing 5 NUM 87
Computer Science
10-I-DB-102-m01 Databases 5 NUM 38
10-I-OOP-102-m01 Object-oriented Programming 5 NUM 39
10-I-AR-102-m01 Automation and Control Technology 8 NUM 40
10-I-BS-102-m01 Operating Systems 5 NUM 41
10-I-RAK-102-m01 Computer Architecture 5 NUM 42
10-I=PVS-102-m01 Programming of Distributed Systems 8 NUM 79
10-I=KI-102-m01 Artificial Intelligence 8 NUM 80
10-I=DB2-102-m01 Databases II 5 NUM 81
10-I=PA-102-m01 Program Design and Analysis 5 NUM 82
Law
02-N-P-H-082-m01 Fundamentals of Commercial Law 4 NUM 34
02-N-P-A-082-m01 Employment Law 4 NUM 35
02-N-P-G-082-m01 Introduction to Companies Law 2 NUM 36
02-N-P-W04-112-m01 European Company Law 2 NUM 130
02-N-P-G1-101-m01 Basic Course German Civil Code 1 10 NUM 116
02-N-P-G2-101-m01 Basic Course German Civil Code 2a and 2 b 10 NUM 117
02-N-P-G3-101-m01 Basic Course German Civil Code 3 10 NUM 118
02-N-P-W06-111-m01 German and European Trade Mark Law 3 NUM 119
02-N-P-W07-111-m01Copyright Law and Fundamentals of Patent Law including refe-
rences to EU Law2 NUM 120
02-J7-112-m01 Employment law for non-law students 3 NUM 124
Information Literacy
41-IK-NW1-101-m01Information Literacy for Students of the Natural Sciences (Ba-
sic Level)2 B/NB 43
41-IK-NW2-101-m01Information Literacy for Students of the Natural Sciences (Ad-
vanced Level)2 B/NB 44
Languages
42-ENO-IK-072-m01 Intercultural Competence (English, Advanced Level) 3 NUM 11
42-ENO-LK-072-m01 Cultural Studies (English, Advanced Level) 3 NUM 12
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
42-ENO-W1-072-m01 English for Business 1 (Advanced Level) 4 NUM 13
42-ENO-W2-072-m01 English for Business 2 (Advanced Level) 4 NUM 14
42-ENO-NW1-072-m01 English for the Natural Sciences 1 (Advanced Level) 4 NUM 27
42-ENO-NW2-072-m01 English for the Natural Sciences 2 (Advanced Level) 4 NUM 28
42-FRO-GW1-072-m01 French for the Humanities 1 (Advanced Level) 4 NUM 15
42-FRO-GW2-072-m01 French for the Humanities 2 (Advanced Level) 4 NUM 16
42-FRO-IK-072-m01 Intercultural Competence (French, Advanced Level) 3 NUM 17
42-FRO-LK-072-m01 Intercultural Competence (French, Advanced Level) 3 NUM 18
42-FRO-W1-072-m01 French for Business 1 (Advanced Level) 4 NUM 19
42-FRO-W2-072-m01 French for Business 2 (Advanced Level) 4 NUM 20
42-SPO-GW1-072-m01 Spanish for the Humanities 1 (Advanced Level) 4 NUM 21
42-SPO-GW2-072-m01 Spanish for the Humanities 2 (Advanced Level) 4 NUM 22
42-SPO-IK-072-m01 Intercultural Competence (Spanish, Advanced Level) 3 NUM 23
42-SPO-LK-072-m01 Cultural Studies (Spanish, Advanced Level) 3 NUM 24
42-SPO-W1-072-m01 Spanish for Business 1 (Advanced Level) 4 NUM 25
42-SPO-W2-072-m01 Spanish for Business 2 (Advanced Level) 4 NUM 26
Additional Qualifications
11-EXNT6-112-m01 Non-technical Minor Subject 6 NUM 131
11-EXZ5-111-m01 Additional Qualifications for Engineers 5 NUM 121
11-EXZ6-111-m01 Additional Qualifications for Engineers 6 NUM 122
Thesis (30 ECTS credits)
11-MA-N-111-m01 Master Thesis Nanostructure Technology 30 NUM 123
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationOperations Research 10-M-ORS-072-m01
Module coordinator Module offered by
Dean of Studies Mathematik (Mathematics) Institute of Mathematics
ECTS Method of grading Only after succ. compl. of module(s)5 numerical grade --
Duration Module level Other prerequisites1 semester undergraduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
Linear programming, duality theory, transport problems, integral linear programming, graph theoretic problems.
Intended learning outcomes
The student is acquainted with the fundamental methods in operations research, as required as a central toolfor solving many practical problems especially in economics. He/She is able to apply these methods to practicalproblems, both theoretically and numerically.
Courses (type, number of weekly contact hours, language — if other than German)
V + Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
written examination (approx. 90 minutes); if announced by the lecturer, the written examination can be replacedby an oral examination of one candidate each (approx. 20 minutes) or an oral examination in groups (groups of2, approx. 30 minutes)Language of assessment: German, English if agreed upon with the examiner
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
§ 73 (1) 5. Mathematik Angewandte Mathematik
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationProfessional Specialization Nanostructure Technology 11-FS-N-072-m01
Module coordinator Module offered by
chairperson of examination committee Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)15 numerical grade --
Duration Module level Other prerequisites1 semester graduate --
Contents
Introduction to current experimental, theoretical or engineering research topics within nanotechnology researchthat are of particular relevance for the envisaged topic of the master thesis. A seminar talk summarizing the re-quired underlying fundamental topics.
Intended learning outcomes
Thorough understanding of a current experimental, theoretical or engineering research topic in the field of nano-technology research chosen for the master thesis. In-depth knowledge of the current state of research and abilityto present and convey this knowledge in a seminar talk.
Courses (type, number of weekly contact hours, language — if other than German)
S (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
talk (approx. 30 to 45 minutes) with discussion
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationScientific Methods and Project Management Nanostructure Technology 11-MP-N-072-m01
Module coordinator Module offered by
chairperson of examination committee Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)15 numerical grade --
Duration Module level Other prerequisites1 semester graduate --
Contents
Introduction to the scientific approach and practice, including project planning within a current experimental, en-gineering or theoretical research topic in the field of nanotechnology research chosen for the master thesis. Esta-blishment of a scientific project plan for the planned
Intended learning outcomes
Knowledge of the scientific approach and practice, including project planning in a current experimental, enginee-ring or theoretical research topic in the field of nanotechnology research chosen for the master thesis. Ability toestablish a research plan for the master thesis, and to plan the required experimental or theoretical work. Abilityto present the project in a seminar talk.
Courses (type, number of weekly contact hours, language — if other than German)
R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
talk (approx. 30 to 45 minutes) with discussion
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationIntercultural Competence (English, Advanced Level) 42-ENO-IK-072-m01
Module coordinator Module offered by
head of Language Centre (ZFS) Language Centre (ZfS)
ECTS Method of grading Only after succ. compl. of module(s)3 numerical grade 42-ENM2 or 42-ENM3 or 42-ENM4 or assessment test
Duration Module level Other prerequisites1 semester undergraduate --
Contents
This module equips students with knowledge and skills that will enable them to act and communicate in inter-cultural situations. It familiarises them with criteria and options for action and equips them with knowledge thatwill allow them to adequately interpret intercultural situations and act appropriately.
Intended learning outcomes
Students develop advanced intercultural and language skills that will allow them to communicate, both verbal-ly and in writing, in a globalised world, taking intercultural aspects into account. They are able to effectively andflexibly use the target language, both during study abroad periods and in the workplace. This module builds onlevel "B2 -- Vantage" and aims to enable students to reach level "C1 -- Effective Operational Proficiency" of theCommon European Framework of Reference for Languages.
Courses (type, number of weekly contact hours, language — if other than German)
Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
option 1: written multi-component examination (approx. 90 minutes total) with 4 components (reading compre-hension, listening comprehension, writing, communication skills) or option 2: oral assessment (approx. 10 mi-nutes) and written multi-component examination (approx. 60 to 90 minutes total) with 3 components (readingcomprehension, listening comprehension, writing) or option 3: 2 to 4 oral assessments (approx. 30 to 60 minu-tes total) as well as 2 to 4 written assessments (approx. 10 to 15 pages total), all components/assessments eachweighted 1:1; options will be selected and examination dates be fixed at the beginning of the courseLanguage of assessment: English
Allocation of places
Number of places: 5-25. Places will be allocated by lot.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationCultural Studies (English, Advanced Level) 42-ENO-LK-072-m01
Module coordinator Module offered by
head of Language Centre (ZFS) Language Centre (ZfS)
ECTS Method of grading Only after succ. compl. of module(s)3 numerical grade 42-ENM2 or 42-ENM3 or 42-ENM4 or assessment test
Duration Module level Other prerequisites1 semester undergraduate --
Contents
This module familiarises students with the culture and society of countries where the target language is spokenand thus enables them to act appropriately in the target language. It discusses the culture, geography, history,society, political system, and the economy of said countries.
Intended learning outcomes
Students develop highly advanced language skills and a thorough familiarity with the culture and society ofcountries where the target language is spoken. They are thus able to communicate, both verbally and in writing,in a variety of situations, taking into account aspects related to the culture and society of said countries. Stu-dents are able to effectively and flexibly use the target language, both during study abroad periods and in theworkplace. This module builds on level "B2 -- Vantage" and aims to enable students to reach level "C1 -- EffectiveOperational Proficiency" of the Common European Framework of Reference for Languages.
Courses (type, number of weekly contact hours, language — if other than German)
Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
option 1: written multi-component examination (approx. 90 minutes total) with 4 components (reading compre-hension, listening comprehension, writing, communication skills) or option 2: oral assessment (approx. 10 mi-nutes) and written multi-component examination (approx. 60 to 90 minutes total) with 3 components (readingcomprehension, listening comprehension, writing) or option 3: 2 to 4 oral assessments (approx. 30 to 60 minu-tes total) as well as 2 to 4 written assessments (approx. 10 to 15 pages total), all components/assessments eachweighted 1:1; options will be selected and examination dates be fixed at the beginning of the courseLanguage of assessment: English
Allocation of places
Number of places: 5-25. Places will be allocated by lot.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationEnglish for Business 1 (Advanced Level) 42-ENO-W1-072-m01
Module coordinator Module offered by
head of Language Centre (ZFS) Language Centre (ZfS)
ECTS Method of grading Only after succ. compl. of module(s)4 numerical grade 42-ENM2 or 42-ENM3 or 42-ENM4 or assessment test
Duration Module level Other prerequisites1 semester undergraduate --
Contents
This module equips students with advanced communication skills in the target language. These will allow themto communicate appropriately, in both written and oral form, at university and in business settings.
Intended learning outcomes
Students gain sound business- and economics-specific communication skills (written and oral) in the target lan-guage. They develop advanced business- and economics-specific language skills that will allow them to commu-nicate about selected topics in corresponding situations, using language flexibly. Students are proficient in busi-ness and economics terminology and are able to communicate effectively within the discipline. At the end of thestage, they will have developed business- and economics-specific language skills that are equivalent to level "C1-- Effective Operational Proficiency" of the Common European Framework of Reference for Languages.
Courses (type, number of weekly contact hours, language — if other than German)
Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
option 1: written multi-component examination (approx. 90 minutes total) with 4 components (reading compre-hension, listening comprehension, writing, communication skills) or option 2: oral assessment (approx. 10 mi-nutes) and written multi-component examination (approx. 60 to 90 minutes total) with 3 components (readingcomprehension, listening comprehension, writing) or option 3: 2 to 4 oral assessments (approx. 30 to 60 minu-tes total) as well as 2 to 4 written assessments (approx. 10 to 15 pages total), all components/assessments eachweighted 1:1; options will be selected and examination dates be fixed at the beginning of the courseAssessment offered: once a year, winter semesterLanguage of assessment: English
Allocation of places
Number of places: 5-25. Places will be allocated by lot.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationEnglish for Business 2 (Advanced Level) 42-ENO-W2-072-m01
Module coordinator Module offered by
head of Language Centre (ZFS) Language Centre (ZfS)
ECTS Method of grading Only after succ. compl. of module(s)4 numerical grade 42-ENM2 or 42-ENM3 or 42-ENM4 or assessment test
Duration Module level Other prerequisites1 semester undergraduate --
Contents
This module equips students with advanced communication skills in the target language. These will allow themto communicate appropriately, in both written and oral form, at university and in business settings.
Intended learning outcomes
Students gain sound business- and economics-specific communication skills (written and oral) in the target lan-guage. They develop advanced business- and economics-specific language skills that will allow them to commu-nicate about selected topics in corresponding situations, using language flexibly. Students are proficient in busi-ness and economics terminology and are able to communicate effectively within the discipline. At the end of thestage, they will have developed business- and economics-specific language skills that are equivalent to level "C1-- Effective Operational Proficiency" of the Common European Framework of Reference for Languages.
Courses (type, number of weekly contact hours, language — if other than German)
Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
option 1: written multi-component examination (approx. 90 minutes total) with 4 components (reading compre-hension, listening comprehension, writing, communication skills) or option 2: oral assessment (approx. 10 mi-nutes) and written multi-component examination (approx. 60 to 90 minutes total) with 3 components (readingcomprehension, listening comprehension, writing) or option 3: 2 to 4 oral assessments (approx. 30 to 60 minu-tes total) as well as 2 to 4 written assessments (approx. 10 to 15 pages total), all components/assessments eachweighted 1:1; options will be selected and examination dates be fixed at the beginning of the courseAssessment offered: once a year, summer semesterLanguage of assessment: English
Allocation of places
Number of places: 5-25. Places will be allocated by lot.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationFrench for the Humanities 1 (Advanced Level) 42-FRO-GW1-072-m01
Module coordinator Module offered by
head of Language Centre (ZFS) Language Centre (ZfS)
ECTS Method of grading Only after succ. compl. of module(s)4 numerical grade 42-FRM2 or 42-FRM3 or 42-FRM4 or assessment test
Duration Module level Other prerequisites1 semester undergraduate --
Contents
This module equips students with advanced communication skills in the target language. These will allow themto communicate appropriately, in both written and oral form, at university and in business settings.
Intended learning outcomes
Students gain sound humanities-specific communication skills (written and oral) in the target language. They de-velop advanced humanities-specific language skills that will allow them to communicate about selected topicsin corresponding situations, using language flexibly. Students are proficient in humanities terminology and areable to communicate effectively within the discipline. At the end of the stage, they will have developed humani-ties-specific language skills that are equivalent to level "C1 -- Effective Operational Proficiency" of the CommonEuropean Framework of Reference for Languages.
Courses (type, number of weekly contact hours, language — if other than German)
Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
option 1: written multi-component examination (approx. 90 minutes total) with 4 components (reading compre-hension, listening comprehension, writing, communication skills) or option 2: oral assessment (approx. 10 mi-nutes) and written multi-component examination (approx. 60 to 90 minutes total) with 3 components (readingcomprehension, listening comprehension, writing) or option 3: 2 to 4 oral assessments (approx. 30 to 60 minu-tes total) as well as 2 to 4 written assessments (approx. 10 to 15 pages total), all components/assessments eachweighted 1:1; options will be selected and examination dates be fixed at the beginning of the courseAssessment offered: once a year, winter semesterLanguage of assessment: French
Allocation of places
Number of places: 5-25. Places will be allocated by lot.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationFrench for the Humanities 2 (Advanced Level) 42-FRO-GW2-072-m01
Module coordinator Module offered by
head of Language Centre (ZFS) Language Centre (ZfS)
ECTS Method of grading Only after succ. compl. of module(s)4 numerical grade 42-FRM2 or 42-FRM3 or 42-FRM4 or assessment test
Duration Module level Other prerequisites1 semester undergraduate --
Contents
This module equips students with advanced communication skills in the target language. These will allow themto communicate appropriately, in both written and oral form, at university and in business settings.
Intended learning outcomes
Students gain sound humanities-specific communication skills (written and oral) in the target language. They de-velop advanced humanities-specific language skills that will allow them to communicate about selected topicsin corresponding situations, using language flexibly. Students are proficient in humanities terminology and areable to communicate effectively within the discipline. At the end of the stage, they will have developed humani-ties-specific language skills that are equivalent to level "C1 -- Effective Operational Proficiency" of the CommonEuropean Framework of Reference for Languages.
Courses (type, number of weekly contact hours, language — if other than German)
Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
option 1: written multi-component examination (approx. 90 minutes total) with 4 components (reading compre-hension, listening comprehension, writing, communication skills) or option 2: oral assessment (approx. 10 mi-nutes) and written multi-component examination (approx. 60 to 90 minutes total) with 3 components (readingcomprehension, listening comprehension, writing) or option 3: 2 to 4 oral assessments (approx. 30 to 60 minu-tes total) as well as 2 to 4 written assessments (approx. 10 to 15 pages total), all components/assessments eachweighted 1:1; options will be selected and examination dates be fixed at the beginning of the courseAssessment offered: once a year, summer semesterLanguage of assessment: French
Allocation of places
Number of places: 5-25. Places will be allocated by lot.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationIntercultural Competence (French, Advanced Level) 42-FRO-IK-072-m01
Module coordinator Module offered by
head of Language Centre (ZFS) Language Centre (ZfS)
ECTS Method of grading Only after succ. compl. of module(s)3 numerical grade 42-FRM2 or 42-FRM3 or 42-FRM4 or assessment test
Duration Module level Other prerequisites1 semester undergraduate --
Contents
This module equips students with knowledge and skills that will enable them to act and communicate in inter-cultural situations. It familiarises them with criteria and options for action and equips them with knowledge thatwill allow them to adequately interpret intercultural situations and act appropriately.
Intended learning outcomes
Students develop advanced intercultural and language skills that will allow them to communicate, both verbal-ly and in writing, in a globalised world, taking intercultural aspects into account. They are able to effectively andflexibly use the target language, both during study abroad periods and in the workplace. This module builds onlevel "B2 -- Vantage" and aims to enable students to reach level "C1 -- Effective Operational Proficiency" of theCommon European Framework of Reference for Languages.
Courses (type, number of weekly contact hours, language — if other than German)
Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
option 1: written multi-component examination (approx. 90 minutes total) with 4 components (reading compre-hension, listening comprehension, writing, communication skills) or option 2: oral assessment (approx. 10 mi-nutes) and written multi-component examination (approx. 60 to 90 minutes total) with 3 components (readingcomprehension, listening comprehension, writing) or option 3: 2 to 4 oral assessments (approx. 30 to 60 minu-tes total) as well as 2 to 4 written assessments (approx. 10 to 15 pages total), all components/assessments eachweighted 1:1; options will be selected and examination dates be fixed at the beginning of the courseLanguage of assessment: French
Allocation of places
Number of places: 5-25. Places will be allocated by lot.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 17 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationIntercultural Competence (French, Advanced Level) 42-FRO-LK-072-m01
Module coordinator Module offered by
head of Language Centre (ZFS) Language Centre (ZfS)
ECTS Method of grading Only after succ. compl. of module(s)3 numerical grade 42-FRM2 or 42-FRM3 or 42-FRM4 or assessment test
Duration Module level Other prerequisites1 semester undergraduate --
Contents
This module familiarises students with the culture and society of countries where the target language is spokenand thus enables them to act appropriately in the target language. It discusses the culture, geography, history,society, political system, and the economy of said countries.
Intended learning outcomes
Students develop highly advanced language skills and a thorough familiarity with the culture and society ofcountries where the target language is spoken. They are thus able to communicate, both verbally and in writing,in a variety of situations, taking into account aspects related to the culture and society of said countries. Stu-dents are able to effectively and flexibly use the target language, both during study abroad periods and in theworkplace. This module builds on level "B2 -- Vantage" and aims to enable students to reach level "C1 -- EffectiveOperational Proficiency" of the Common European Framework of Reference for Languages.
Courses (type, number of weekly contact hours, language — if other than German)
Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
option 1: written multi-component examination (approx. 90 minutes total) with 4 components (reading compre-hension, listening comprehension, writing, communication skills) or option 2: oral assessment (approx. 10 mi-nutes) and written multi-component examination (approx. 60 to 90 minutes total) with 3 components (readingcomprehension, listening comprehension, writing) or option 3: 2 to 4 oral assessments (approx. 30 to 60 minu-tes total) as well as 2 to 4 written assessments (approx. 10 to 15 pages total), all components/assessments eachweighted 1:1; options will be selected and examination dates be fixed at the beginning of the courseLanguage of assessment: French
Allocation of places
Number of places: 5-25. Places will be allocated by lot.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 18 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationFrench for Business 1 (Advanced Level) 42-FRO-W1-072-m01
Module coordinator Module offered by
head of Language Centre (ZFS) Language Centre (ZfS)
ECTS Method of grading Only after succ. compl. of module(s)4 numerical grade 42-FRM2 or 42-FRM3 or 42-FRM4 or assessment test
Duration Module level Other prerequisites1 semester undergraduate --
Contents
This module equips students with advanced communication skills in the target language. These will allow themto communicate appropriately, in both written and oral form, at university and in business settings.
Intended learning outcomes
Students gain sound business- and economics-specific communication skills (written and oral) in the target lan-guage. They develop advanced business- and economics-specific language skills that will allow them to commu-nicate about selected topics in corresponding situations, using language flexibly. Students are proficient in busi-ness and economics terminology and are able to communicate effectively within the discipline. At the end of thestage, they will have developed business- and economics-specific language skills that are equivalent to level "C1-- Effective Operational Proficiency" of the Common European Framework of Reference for Languages.
Courses (type, number of weekly contact hours, language — if other than German)
Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
option 1: written multi-component examination (approx. 90 minutes total) with 4 components (reading compre-hension, listening comprehension, writing, communication skills) or option 2: oral assessment (approx. 10 mi-nutes) and written multi-component examination (approx. 60 to 90 minutes total) with 3 components (readingcomprehension, listening comprehension, writing) or option 3: 2 to 4 oral assessments (approx. 30 to 60 minu-tes total) as well as 2 to 4 written assessments (approx. 10 to 15 pages total), all components/assessments eachweighted 1:1; options will be selected and examination dates be fixed at the beginning of the courseAssessment offered: once a year, winter semesterLanguage of assessment: French
Allocation of places
Number of places: 5-25. Places will be allocated by lot.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 19 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationFrench for Business 2 (Advanced Level) 42-FRO-W2-072-m01
Module coordinator Module offered by
head of Language Centre (ZFS) Language Centre (ZfS)
ECTS Method of grading Only after succ. compl. of module(s)4 numerical grade 42-FRM2 or 42-FRM3 or 42-FRM4 or assessment test
Duration Module level Other prerequisites1 semester undergraduate --
Contents
This module equips students with advanced communication skills in the target language. These will allow themto communicate appropriately, in both written and oral form, at university and in business settings.
Intended learning outcomes
Students gain sound business- and economics-specific communication skills (written and oral) in the target lan-guage. They develop advanced business- and economics-specific language skills that will allow them to commu-nicate about selected topics in corresponding situations, using language flexibly. Students are proficient in busi-ness and economics terminology and are able to communicate effectively within the discipline. At the end of thestage, they will have developed business- and economics-specific language skills that are equivalent to level "C1-- Effective Operational Proficiency" of the Common European Framework of Reference for Languages.
Courses (type, number of weekly contact hours, language — if other than German)
Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
option 1: written multi-component examination (approx. 90 minutes total) with 4 components (reading compre-hension, listening comprehension, writing, communication skills) or option 2: oral assessment (approx. 10 mi-nutes) and written multi-component examination (approx. 60 to 90 minutes total) with 3 components (readingcomprehension, listening comprehension, writing) or option 3: 2 to 4 oral assessments (approx. 30 to 60 minu-tes total) as well as 2 to 4 written assessments (approx. 10 to 15 pages total), all components/assessments eachweighted 1:1; options will be selected and examination dates be fixed at the beginning of the courseAssessment offered: once a year, summer semesterLanguage of assessment: French
Allocation of places
Number of places: 5-25. Places will be allocated by lot.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 20 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationSpanish for the Humanities 1 (Advanced Level) 42-SPO-GW1-072-m01
Module coordinator Module offered by
head of Language Centre (ZFS) Language Centre (ZfS)
ECTS Method of grading Only after succ. compl. of module(s)4 numerical grade 42-SPM2 or 42-SPM3 or 42-SPM4 or assessment test
Duration Module level Other prerequisites1 semester undergraduate --
Contents
This module equips students with advanced communication skills in the target language. These will allow themto communicate appropriately, in both written and oral form, in situations involving humanistic topics.
Intended learning outcomes
Students gain sound humanities-specific communication skills (written and oral) in the target language. They de-velop advanced humanities-specific language skills that will allow them to communicate about selected topicsin corresponding situations, using language flexibly. Students are proficient in humanities terminology and areable to communicate effectively within the discipline. At the end of the stage, they will have developed humani-ties-specific language skills that are equivalent to level "C1 -- Effective Operational Proficiency" of the CommonEuropean Framework of Reference for Languages.
Courses (type, number of weekly contact hours, language — if other than German)
Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
option 1: written multi-component examination (approx. 90 minutes total) with 4 components (reading compre-hension, listening comprehension, writing, communication skills) or option 2: oral assessment (approx. 10 mi-nutes) and written multi-component examination (approx. 60 to 90 minutes total) with 3 components (readingcomprehension, listening comprehension, writing) or option 3: 2 to 4 oral assessments (approx. 30 to 60 minu-tes total) as well as 2 to 4 written assessments (approx. 10 to 15 pages total), all components/assessments eachweighted 1:1; options will be selected and examination dates be fixed at the beginning of the courseAssessment offered: once a year, winter semesterLanguage of assessment: Spanish
Allocation of places
Number of places: 5-25. Places will be allocated by lot.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 21 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationSpanish for the Humanities 2 (Advanced Level) 42-SPO-GW2-072-m01
Module coordinator Module offered by
head of Language Centre (ZFS) Language Centre (ZfS)
ECTS Method of grading Only after succ. compl. of module(s)4 numerical grade 42-SPM2 or 42-SPM3 or 42-SPM4 or assessment test
Duration Module level Other prerequisites1 semester undergraduate --
Contents
This module equips students with advanced communication skills in the target language. These will allow themto communicate appropriately, in both written and oral form, in situations involving humanistic topics.
Intended learning outcomes
Students gain sound humanities-specific communication skills (written and oral) in the target language. They de-velop advanced humanities-specific language skills that will allow them to communicate about selected topicsin corresponding situations, using language flexibly. Students are proficient in humanities terminology and areable to communicate effectively within the discipline. At the end of the stage, they will have developed humani-ties-specific language skills that are equivalent to level "C1 -- Effective Operational Proficiency" of the CommonEuropean Framework of Reference for Languages.
Courses (type, number of weekly contact hours, language — if other than German)
Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
option 1: written multi-component examination (approx. 90 minutes total) with 4 components (reading compre-hension, listening comprehension, writing, communication skills) or option 2: oral assessment (approx. 10 mi-nutes) and written multi-component examination (approx. 60 to 90 minutes total) with 3 components (readingcomprehension, listening comprehension, writing) or option 3: 2 to 4 oral assessments (approx. 30 to 60 minu-tes total) as well as 2 to 4 written assessments (approx. 10 to 15 pages total), all components/assessments eachweighted 1:1; options will be selected and examination dates be fixed at the beginning of the courseAssessment offered: once a year, summer semesterLanguage of assessment: Spanish
Allocation of places
Number of places: 5-25. Places will be allocated by lot.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 22 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationIntercultural Competence (Spanish, Advanced Level) 42-SPO-IK-072-m01
Module coordinator Module offered by
head of Language Centre (ZFS) Language Centre (ZfS)
ECTS Method of grading Only after succ. compl. of module(s)3 numerical grade 42-SPM2 or 42-SPM3 or 42-SPM4 or assessment test
Duration Module level Other prerequisites1 semester undergraduate --
Contents
This module equips students with knowledge and skills that will enable them to act and communicate in inter-cultural situations. It familiarises them with criteria and options for action and equips them with knowledge thatwill allow them to adequately interpret intercultural situations and act appropriately.
Intended learning outcomes
Students develop advanced intercultural and language skills that will allow them to communicate, both verbal-ly and in writing, in a globalised world, taking intercultural aspects into account. They are able to effectively andflexibly use the target language, both during study abroad periods and in the workplace. This module builds onlevel "B2 -- Vantage" and aims to enable students to reach level "C1 -- Effective Operational Proficiency" of theCommon European Framework of Reference for Languages.
Courses (type, number of weekly contact hours, language — if other than German)
Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
option 1: written multi-component examination (approx. 90 minutes total) with 4 components (reading compre-hension, listening comprehension, writing, communication skills) or option 2: oral assessment (approx. 10 mi-nutes) and written multi-component examination (approx. 60 to 90 minutes total) with 3 components (readingcomprehension, listening comprehension, writing) or option 3: 2 to 4 oral assessments (approx. 30 to 60 minu-tes total) as well as 2 to 4 written assessments (approx. 10 to 15 pages total), all components/assessments eachweighted 1:1; options will be selected and examination dates be fixed at the beginning of the courseLanguage of assessment: Spanish
Allocation of places
Number of places: 5-25. Places will be allocated by lot.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 23 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationCultural Studies (Spanish, Advanced Level) 42-SPO-LK-072-m01
Module coordinator Module offered by
head of Language Centre (ZFS) Language Centre (ZfS)
ECTS Method of grading Only after succ. compl. of module(s)3 numerical grade 42-SPM2 or 42-SPM3 or 42-SPM4 or assessment test
Duration Module level Other prerequisites1 semester undergraduate --
Contents
This module familiarises students with the culture and society of countries where the target language is spokenand thus enables them to act appropriately in the target language. It discusses the culture, geography, history,society, political system, and the economy of said countries.
Intended learning outcomes
Students develop highly advanced language skills and a thorough familiarity with the culture and society ofcountries where the target language is spoken. They are thus able to communicate, both verbally and in writing,in a variety of situations, taking into account aspects related to the culture and society of said countries. Stu-dents are able to effectively and flexibly use the target language, both during study abroad periods and in theworkplace. This module builds on level "B2 -- Vantage" and aims to enable students to reach level "C1 -- EffectiveOperational Proficiency" of the Common European Framework of Reference for Languages.
Courses (type, number of weekly contact hours, language — if other than German)
Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
option 1: written multi-component examination (approx. 90 minutes total) with 4 components (reading compre-hension, listening comprehension, writing, communication skills) or option 2: oral assessment (approx. 10 mi-nutes) and written multi-component examination (approx. 60 to 90 minutes total) with 3 components (readingcomprehension, listening comprehension, writing) or option 3: 2 to 4 oral assessments (approx. 30 to 60 minu-tes total) as well as 2 to 4 written assessments (approx. 10 to 15 pages total), all components/assessments eachweighted 1:1; options will be selected and examination dates be fixed at the beginning of the courseLanguage of assessment: Spanish
Allocation of places
Number of places: 5-25. Places will be allocated by lot.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 24 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationSpanish for Business 1 (Advanced Level) 42-SPO-W1-072-m01
Module coordinator Module offered by
head of Language Centre (ZFS) Language Centre (ZfS)
ECTS Method of grading Only after succ. compl. of module(s)4 numerical grade 42-SPM2 or 42-SPM3 or 42-SPM4 or assessment test
Duration Module level Other prerequisites1 semester undergraduate --
Contents
This module equips students with advanced communication skills in the target language. These will allow themto communicate appropriately, in both written and oral form, at university and in business settings.
Intended learning outcomes
Students gain sound business- and economics-specific communication skills (written and oral) in the target lan-guage. They develop advanced business- and economics-specific language skills that will allow them to commu-nicate about selected topics in corresponding situations, using language flexibly. Students are proficient in busi-ness and economics terminology and are able to communicate effectively within the discipline. At the end of thestage, they will have developed business- and economics-specific language skills that are equivalent to level "C1-- Effective Operational Proficiency" of the Common European Framework of Reference for Languages.
Courses (type, number of weekly contact hours, language — if other than German)
Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
option 1: written multi-component examination (approx. 90 minutes total) with 4 components (reading compre-hension, listening comprehension, writing, communication skills) or option 2: oral assessment (approx. 10 mi-nutes) and written multi-component examination (approx. 60 to 90 minutes total) with 3 components (readingcomprehension, listening comprehension, writing) or option 3: 2 to 4 oral assessments (approx. 30 to 60 minu-tes total) as well as 2 to 4 written assessments (approx. 10 to 15 pages total), all components/assessments eachweighted 1:1; options will be selected and examination dates be fixed at the beginning of the courseAssessment offered: once a year, winter semesterLanguage of assessment: Spanish
Allocation of places
Number of places: 5-25. Places will be allocated by lot.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 25 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationSpanish for Business 2 (Advanced Level) 42-SPO-W2-072-m01
Module coordinator Module offered by
head of Language Centre (ZFS) Language Centre (ZfS)
ECTS Method of grading Only after succ. compl. of module(s)4 numerical grade 42-SPM2 or 42-SPM3 or 42-SPM4 or assessment test
Duration Module level Other prerequisites1 semester undergraduate --
Contents
This module equips students with advanced communication skills in the target language. These will allow themto communicate appropriately, in both written and oral form, at university and in business settings.
Intended learning outcomes
Students gain sound business- and economics-specific communication skills (written and oral) in the target lan-guage. They develop advanced business- and economics-specific language skills that will allow them to commu-nicate about selected topics in corresponding situations, using language flexibly. Students are proficient in busi-ness and economics terminology and are able to communicate effectively within the discipline. At the end of thestage, they will have developed business- and economics-specific language skills that are equivalent to level "C1-- Effective Operational Proficiency" of the Common European Framework of Reference for Languages.
Courses (type, number of weekly contact hours, language — if other than German)
Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
option 1: written multi-component examination (approx. 90 minutes total) with 4 components (reading compre-hension, listening comprehension, writing, communication skills) or option 2: oral assessment (approx. 10 mi-nutes) and written multi-component examination (approx. 60 to 90 minutes total) with 3 components (readingcomprehension, listening comprehension, writing) or option 3: 2 to 4 oral assessments (approx. 30 to 60 minu-tes total) as well as 2 to 4 written assessments (approx. 10 to 15 pages total), all components/assessments eachweighted 1:1; options will be selected and examination dates be fixed at the beginning of the courseAssessment offered: once a year, summer semesterLanguage of assessment: Spanish
Allocation of places
Number of places: 5-25. Places will be allocated by lot.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 26 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationEnglish for the Natural Sciences 1 (Advanced Level) 42-ENO-NW1-072-m01
Module coordinator Module offered by
head of Language Centre (ZFS) Language Centre (ZfS)
ECTS Method of grading Only after succ. compl. of module(s)4 numerical grade 42-ENM2 or 42-ENM3 or 42-ENM4 or assessment test
Duration Module level Other prerequisites1 semester undergraduate --
Contents
This module equips students with advanced communication skills in the target language. These will allow themto communicate appropriately, in both written and oral form, in science-oriented situations.
Intended learning outcomes
Students gain sound natural sciences-specific communication skills (written and oral) in the target language.They develop advanced natural sciences-specific language skills that will allow them to communicate about se-lected topics in corresponding situations, using language flexibly. Students are proficient in scientific terminolo-gy and are able to communicate effectively within the discipline. At the end of the stage, they will have develo-ped natural sciences-specific language skills that are equivalent to level "C1 -- Effective Operational Proficiency"of the Common European Framework of Reference for Languages.
Courses (type, number of weekly contact hours, language — if other than German)
Ü + Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
option 1: written multi-component examination (approx. 90 minutes total) with 4 components (reading compre-hension, listening comprehension, writing, communication skills) or option 2: oral assessment (approx. 10 mi-nutes) and written multi-component examination (approx. 60 to 90 minutes total) with 3 components (readingcomprehension, listening comprehension, writing) or option 3: 2 to 4 oral assessments (approx. 30 to 60 minu-tes total) as well as 2 to 4 written assessments (approx. 10 to 15 pages total), all components/assessments eachweighted 1:1; options will be selected and examination dates be fixed at the beginning of the courseAssessment offered: once a year, winter semesterLanguage of assessment: English
Allocation of places
Number of places: 5-25. Places will be allocated by lot.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationEnglish for the Natural Sciences 2 (Advanced Level) 42-ENO-NW2-072-m01
Module coordinator Module offered by
head of Language Centre (ZFS) Language Centre (ZfS)
ECTS Method of grading Only after succ. compl. of module(s)4 numerical grade 42-ENM2 or 42-ENM3 or 42-ENM4 or assessment test
Duration Module level Other prerequisites1 semester undergraduate --
Contents
This module equips students with advanced communication skills in the target language. These will allow themto communicate appropriately, in both written and oral form, in science-oriented situations.
Intended learning outcomes
Students gain sound natural sciences-specific communication skills (written and oral) in the target language.They develop advanced natural sciences-specific language skills that will allow them to communicate about se-lected topics in corresponding situations, using language flexibly. Students are proficient in scientific terminolo-gy and are able to communicate effectively within the discipline. At the end of the stage, they will have develo-ped natural sciences-specific language skills that are equivalent to level "C1 -- Effective Operational Proficiency"of the Common European Framework of Reference for Languages.
Courses (type, number of weekly contact hours, language — if other than German)
Ü + Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
option 1: written multi-component examination (approx. 90 minutes total) with 4 components (reading compre-hension, listening comprehension, writing, communication skills) or option 2: oral assessment (approx. 10 mi-nutes) and written multi-component examination (approx. 60 to 90 minutes total) with 3 components (readingcomprehension, listening comprehension, writing) or option 3: 2 to 4 oral assessments (approx. 30 to 60 minu-tes total) as well as 2 to 4 written assessments (approx. 10 to 15 pages total), all components/assessments eachweighted 1:1; options will be selected and examination dates be fixed at the beginning of the courseAssessment offered: once a year, summer semesterLanguage of assessment: English
Allocation of places
Number of places: 5-25. Places will be allocated by lot.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationNumerical Mathematics 1 10-M-NM1-082-m01
Module coordinator Module offered by
Dean of Studies Mathematik (Mathematics) Institute of Mathematics
ECTS Method of grading Only after succ. compl. of module(s)8 numerical grade --
Duration Module level Other prerequisites1 semester undergraduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
Solution of systems of linear equations and curve fitting problems, nonlinear equations and systems of equati-ons, interpolation with polynomials, splines and trigonometric functions, numerical integration.
Intended learning outcomes
The student is acquainted with the fundamental concepts and methods in numerical mathematics, applies themto practical problems and knows about their typical fields of application.
Courses (type, number of weekly contact hours, language — if other than German)
V + Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
written examination (approx. 90 minutes); if announced by the lecturer, the written examination can be replacedby an oral examination of one candidate each (approx. 20 minutes) or an oral examination in groups (groups of2, approx. 30 minutes)Language of assessment: German, English if agreed upon with the examiner
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
§ 73 (1) 5. Mathematik Angewandte Mathematik
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationNumerical Mathematics 2 10-M-NM2-082-m01
Module coordinator Module offered by
Dean of Studies Mathematik (Mathematics) Institute of Mathematics
ECTS Method of grading Only after succ. compl. of module(s)5 numerical grade --
Duration Module level Other prerequisites1 semester undergraduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
Solution methods and applications for eigenvalue problems, linear programming, initial value problems for ordi-nary differential equations, boundary value problems.
Intended learning outcomes
The student is able to draw a distinction between the different concepts of numerical mathematics and knowsabout their advantages and limitations concerning the possibilities of application in different fields of naturaland engineering sciences and economics.
Courses (type, number of weekly contact hours, language — if other than German)
V + Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
written examination (approx. 90 minutes); if announced by the lecturer, the written examination can be replacedby an oral examination of one candidate each (approx. 20 minutes) or an oral examination in groups (groups of2, approx. 30 minutes)Language of assessment: German, English if agreed upon with the examiner
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
§ 73 (1) 5. Mathematik Angewandte Mathematik
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationAdvanced Analysis 10-M-VAN-082-m01
Module coordinator Module offered by
Dean of Studies Mathematik (Mathematics) Institute of Mathematics
ECTS Method of grading Only after succ. compl. of module(s)8 numerical grade --
Duration Module level Other prerequisites1 semester undergraduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
Lebesgue integral in several variables, including theorems on convergence and Fubini's theorem, L^p-spacesand elementary Fourier theory in L^2, Gauss's theorem.
Intended learning outcomes
The student is acquainted with advanced topics in analysis. Taking the example of the Lesbegue integral, he orshe is able to understand the construction of a complex mathematical concept.
Courses (type, number of weekly contact hours, language — if other than German)
Ü + V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
written examination (approx. 90 minutes); if announced by the lecturer, the written examination can be replacedby an oral examination of one candidate each (approx. 20 minutes) or an oral examination in groups (groups of2, approx. 30 minutes)Language of assessment: German, English if agreed upon with the examiner
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
§ 73 (1) 1. Mathematik Analysis
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationTechnology of Sensor and Actor Materials including Smart Fluids 08-SAM-092-m01
Module coordinator Module offered by
holder of the Chair of Chemical Technology of Material Syn-thesis
Chair of Chemical Technology of Material Synthesis
ECTS Method of grading Only after succ. compl. of module(s)5 numerical grade --
Duration Module level Other prerequisites1 semester graduate --
Contents
German contents available but not translated yet. Herstellung, Wirkungsweise und Anwendungen sensorischer und aktorischer Materialien wie Piezoelektrika,Formgedächtnismaterialien, magnetostriktive Materialien. Elektrorheologische und magnetorheologische Flüs-sigkeiten, Magnetofluide.
Intended learning outcomes
German intended learning outcomes available but not translated yet. Der/Die Studierende verfügt über grundlegende Kenntnisse im Bereich der sensorischen und aktorischen Mate-rialien.
Courses (type, number of weekly contact hours, language — if other than German)
V + P (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
written examination (90 minutes)
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationOrganic Semiconductor 11-OHL-092-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)5 numerical grade --
Duration Module level Other prerequisites1 semester graduate Admission prerequisite to assessment: successful completion of approx.
50% of exercises. Certain prerequisites must be met to qualify for admis-sion to assessment. The lecturer will inform students about the respecti-ve details at the beginning of the course. Registration for the course willbe considered a declaration of will to seek admission to assessment. Ifstudents have obtained the qualification for admission to assessmentover the course of the semester, the lecturer will put their registration forassessment into effect. Students who meet all prerequisites will be ad-mitted to assessment in the current or in the subsequent semester. Forassessment at a later date, students will have to obtain the qualificationfor admission to assessment anew.
Contents
Fundamentals of organic semiconductors, molecular and polymer electronics and sensor technology, applicati-ons.
Intended learning outcomes
In-depth knowledge of the properties of organic semiconductor materials and their applications.
Courses (type, number of weekly contact hours, language — if other than German)
V + Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation (ap-prox. 30 minutes)
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationFundamentals of Commercial Law 02-N-P-H-082-m01
Module coordinator Module offered by
Dean of Studies Faculty of Law Faculty of Law
ECTS Method of grading Only after succ. compl. of module(s)4 numerical grade --
Duration Module level Other prerequisites1 semester undergraduate --
Contents
German contents available but not translated yet. Das Modul erschließt den zentralen Bereich des Handelsrechts.
Intended learning outcomes
German intended learning outcomes available but not translated yet. Die Studierenden haben umfassende Kenntnisse auf dem Gebiet des Handelsrechts erworben. Sie haben sichinsbesondere mit den Vorschriften über die Kaufleute, das Handelsregister, die Handelsfirma, Prokura, Hand-lungsvollmacht, sowie den allgemeinen Vorschriften über Handelsgeschäfte und den Handelskauf beschäftigt.
Courses (type, number of weekly contact hours, language — if other than German)
V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 120 minutes) or b) oral examination (approx. 15 minutes)
Allocation of places
Degree programm law (degree "Erste Juristische Staatsprüfung") and Bachelor's Privatrecht (Private Law) (minorwith 60 ECTS credits): no restrictions. Students of other degree programmes: 20 places. Places will be allocatedas follows: Students applying after not having successfully completed assessment in in the last two semesterswill be given preferential consideration. The remaining places will be allocated by lot. A waiting list will be main-tained and places re-allocated as they become available.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationEmployment Law 02-N-P-A-082-m01
Module coordinator Module offered by
Dean of Studies Faculty of Law Faculty of Law
ECTS Method of grading Only after succ. compl. of module(s)4 numerical grade --
Duration Module level Other prerequisites1 semester undergraduate --
Contents
German contents available but not translated yet. Die Veranstaltung verschafft den Studierenden einen Überblick über System und Struktur des Arbeitsrechts undgeht dabei auf die wichtigsten Problembereiche ein.
Intended learning outcomes
German intended learning outcomes available but not translated yet. Die Studierenden haben umfassende Kenntnisse auf dem Gebiet des Individualrechts erworben. Daneben habensie sich mit bedeutenden Fragestellungen des Kollektivarbeitsrechts auseinandergesetzt.
Courses (type, number of weekly contact hours, language — if other than German)
V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 120 minutes) or b) oral examination (approx. 15 minutes)
Allocation of places
Degree programm law (degree "Erste Juristische Staatsprüfung") and Bachelor's Privatrecht (Private Law) (minorwith 60 ECTS credits): no restrictions. Students of other degree programmes: 20 places. Places will be allocatedas follows: Students applying after not having successfully completed assessment in in the last two semesterswill be given preferential consideration. The remaining places will be allocated by lot. A waiting list will be main-tained and places re-allocated as they become available.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationIntroduction to Companies Law 02-N-P-G-082-m01
Module coordinator Module offered by
Dean of Studies Faculty of Law Faculty of Law
ECTS Method of grading Only after succ. compl. of module(s)2 numerical grade --
Duration Module level Other prerequisites1 semester undergraduate --
Contents
German contents available but not translated yet. Gegenstand der Vorlesung sind Grundzüge des Rechts der Personengesellschaften und der GmbH.
Intended learning outcomes
German intended learning outcomes available but not translated yet. Die Studierenden haben wesentliche Kenntnisse über die Personengesellschaften, insbesondere die oHG unddie GbR erlangt. Darüber hinaus haben sie Einblicke in das Recht der Kapitalgesellschaften erhalten.
Courses (type, number of weekly contact hours, language — if other than German)
V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 120 minutes) or b) oral examination (approx. 15 minutes)
Allocation of places
Degree programm law (degree "Erste Juristische Staatsprüfung") and Bachelor's Privatrecht (Private Law) (minorwith 60 ECTS credits): no restrictions. Students of other degree programmes: 20 places. Places will be allocatedas follows: Students applying after not having successfully completed assessment in in the last two semesterswill be given preferential consideration. The remaining places will be allocated by lot. A waiting list will be main-tained and places re-allocated as they become available.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationElectrochemical Energy Storage and Conversion 08-EEW-101-m01
Module coordinator Module offered by
holder of the Chair of Chemical Technology of Material Syn-thesis
Chair of Chemical Technology of Material Synthesis
ECTS Method of grading Only after succ. compl. of module(s)5 numerical grade --
Duration Module level Other prerequisites1 semester graduate --
Contents
Chemistry and application of: battery systems (aqueous and non-aqueous systems like lead, nickel cadmiumand nickel metal hydride, sodium sulfur, sodium nickel chloride, lithium ion accumulators), electrochemical dou-ble layer capacitors, redox-flow battery, fuel cell systems (AFC, PEMFC, DMFC, PAFC, SOFC), Solar cells (Si, CIS,CIGS, GaAs, organic and dye solar cell), thermoelectric devices.
Intended learning outcomes
The students posess comprehensive knowledge in the field of electrochemical energy storage and transformati-on and are able to apply this to scientific problems.
Courses (type, number of weekly contact hours, language — if other than German)
V + P + E (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
written examination (90 minutes) and lab report (approx. 5 pages)
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationDatabases 10-I-DB-102-m01
Module coordinator Module offered by
Dean of Studies Informatik (Computer Science) Institute of Computer Science
ECTS Method of grading Only after succ. compl. of module(s)5 numerical grade --
Duration Module level Other prerequisites1 semester undergraduate Admission prerequisite to assessment: exercises (type and scope to be
announced by the lecturer at the beginning of the course).
Contents
Relational algebra and complex SQL statements; database planning and normal forms; transaction manage-ment.
Intended learning outcomes
The students possess knowledge about database modelling and queries in SQL as well as transactions.
Courses (type, number of weekly contact hours, language — if other than German)
V + Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
written examination (approx. 50 to 60 minutes); if announced by the lecturer by four weeks prior to the examina-tion date, the written examination can be replaced by an oral examination of one candidate each or an oral ex-amination in groups (one candidate each: 15 minutes, groups of 2: 20 minutes, groups of 3: 25 minutes)Language of assessment: German, English if agreed upon with the examiner
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
§ 49 (1) 1. b) Datenbanksysteme und Softwaretechnologie§ 69 (1) 1. b) Datenbanksysteme und Softwaretechnologie
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationObject-oriented Programming 10-I-OOP-102-m01
Module coordinator Module offered by
Dean of Studies Informatik (Computer Science) Institute of Computer Science
ECTS Method of grading Only after succ. compl. of module(s)5 numerical grade --
Duration Module level Other prerequisites1 semester undergraduate Admission prerequisite to assessment: exercises (type and scope to be
announced by the lecturer at the beginning of the course).
Contents
Polymorphism, generic programming, meta programming, web programming, templates, document manage-ment.
Intended learning outcomes
The students are proficient in the different paradigms of object-oriented programming and have experience intheir practical use.
Courses (type, number of weekly contact hours, language — if other than German)
V + Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
written examination (approx. 50 to 60 minutes); if announced by the lecturer by four weeks prior to the examina-tion date, the written examination can be replaced by an oral examination of one candidate each or an oral ex-amination in groups (one candidate each: 15 minutes, groups of 2: 20 minutes, groups of 3: 25 minutes)Language of assessment: German, English if agreed upon with the examiner
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationAutomation and Control Technology 10-I-AR-102-m01
Module coordinator Module offered by
holder of the Chair of Computer Science VII Institute of Computer Science
ECTS Method of grading Only after succ. compl. of module(s)8 numerical grade --
Duration Module level Other prerequisites1 semester undergraduate Admission prerequisite to assessment: exercises (type and scope to be
announced by the lecturer at the beginning of the course).
Contents
Overview of automation systems, fundamental principles of control technology, Laplace transformation, transferfunction, plant, controller types, basic feedback loop, fundamental principles of control engineering, automata,structure of Petri nets, Petri nets for automisation, machine-related structure of processing computation machi-nes, communication between process computers and periphery devices, software for automation systems, pro-cess synchronisation, process communication, real-time operating systems, real-time planning.
Intended learning outcomes
The students master the fundamentals of automation and control.
Courses (type, number of weekly contact hours, language — if other than German)
V + Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
written examination (approx. 80 to 90 minutes). If announced by the lecturer by four weeks prior to the examina-tion date, the written examination can be replaced by an oral examination of one candidate each or an oral ex-amination in groups. A 80 to 90 minute written examination is equivalent to a 20 minute (approx.) oral examina-tion of one candidate each, a 30 minute (approx.) oral examination in groups of 2 and a 40 minute (approx.) oralexamination in groups of 3.Language of assessment: German, English if agreed upon with the examiner
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationOperating Systems 10-I-BS-102-m01
Module coordinator Module offered by
holder of the Chair of Computer Science II Institute of Computer Science
ECTS Method of grading Only after succ. compl. of module(s)5 numerical grade --
Duration Module level Other prerequisites1 semester undergraduate Admission prerequisite to assessment: exercises (type and scope to be
announced by the lecturer at the beginning of the course).
Contents
Batch, time sharing, real-time virtual machines, system calls, processes and threads, cooperating processes,schedulers, process synchronisation, semaphores, monitors, critical regions, deadlocks, dynamic memory ma-nagement, segmentation, paging, file systems, interfaces, directory structure, network file systems, hard driveorganisation, basics of MS operating systems.
Intended learning outcomes
The students possess knowledge and practical skills in building and using essential parts of operating systems.
Courses (type, number of weekly contact hours, language — if other than German)
V + Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
written examination (approx. 50 to 60 minutes); if announced by the lecturer by four weeks prior to the examina-tion date, the written examination can be replaced by an oral examination of one candidate each or an oral ex-amination in groups (one candidate each: 15 minutes, groups of 2: 20 minutes, groups of 3: 25 minutes)Language of assessment: German, English if agreed upon with the examiner
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
§ 69 (1) 1. c) Informatik Technische Informatik
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationComputer Architecture 10-I-RAK-102-m01
Module coordinator Module offered by
holder of the Chair of Computer Science V Institute of Computer Science
ECTS Method of grading Only after succ. compl. of module(s)5 numerical grade --
Duration Module level Other prerequisites1 semester undergraduate Admission prerequisite to assessment: exercises (type and scope to be
announced by the lecturer at the beginning of the course).
Contents
Instruction set architectures, command processing through pipelining, statical and dynamic instruction schedu-ling, caches, vector processors, multi-core processors.
Intended learning outcomes
The students master the most important techniques to design fast computers as well as their interaction withcompilers and operating systems.
Courses (type, number of weekly contact hours, language — if other than German)
V + Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
written examination (approx. 50 to 60 minutes); if announced by the lecturer by four weeks prior to the examina-tion date, the written examination can be replaced by an oral examination of one candidate each or an oral ex-amination in groups (one candidate each: 15 minutes, groups of 2: 20 minutes, groups of 3: 25 minutes)Language of assessment: German, English if agreed upon with the examiner
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
§ 69 (1) 1. c) Informatik Technische Informatik
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationInformation Literacy for Students of the Natural Sciences (Basic Level) 41-IK-NW1-101-m01
Module coordinator Module offered by
head of University Library University Library
ECTS Method of grading Only after succ. compl. of module(s)2 (not) successfully completed --
Duration Module level Other prerequisites1 semester undergraduate --
Contents
Information literacy in an academic context:- Search strategies and tools.- Using the library's electronic resources.- Resources for natural sciences: databases and journals.- Online searches and search engines.- Overview of additional resources (eLearning etc.).- Reference management. Some sections of the module will focus on particular disciplines (wherever possible,on disciplines in the natural sciences).
Intended learning outcomes
Students know what information is needed for what purpose. They are able to locate information that is relevantwithin their discipline and beyond in a variety of resources and to evaluate this information. They recognise thedifference in quality between information they have retrieved from specific, restricted access resources (databa-ses) and information they have found on the free web. Students are able to manage and process the informationthey have found, using reference management software and eLearning tools. The module aims to equip studentswith the skills needed to find information and literature that is relevant to the topics of their Bachelor's theses.
Courses (type, number of weekly contact hours, language — if other than German)
Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 60 minutes) or b) preparing and delivering a presentation with slides (approx.10 minutes or approx. 5 minutes and approx. 1 page) or c) completing exercises (approx. 10 exercises) or d) pre-sentation without slides (approx. 20 to 30 minutes) or e) preparing and delivering a presentation with slides (ap-prox. 5 minutes) and completing exercises (approx. 5 exercises) or f) presentation without slides (approx. 10 to15 minutes) and completing exercises (approx. 5 exercises)
Allocation of places
Number of places: 5-50. There is a restricted number of places. If necessary, places will be allocated as follows:Students of the degree programmes of the respective subject-specific focuses will be given preferential conside-ration. The remaining places, if and when any become available, will be allocated to students of the other naturalsciences degree programmes. In each of the above-mentioned groups, 30% of places will be allocated accordingto the number of subject semesters. Among applicants with the same number of subject semesters, places willbe allocated by lot. The remaining 70% of places will each be allocated by lot.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationInformation Literacy for Students of the Natural Sciences (Advanced Level) 41-IK-NW2-101-m01
Module coordinator Module offered by
head of University Library University Library
ECTS Method of grading Only after succ. compl. of module(s)2 (not) successfully completed --
Duration Module level Other prerequisites1 semester undergraduate Knowledge and skills equivalent to those achieved in the basic module
desirable.
Contents
Information literacy in an academic context:- More in-depth discussion of selected topics that were covered in the level one module, e. g. searching sub-ject-specific databases.- Publishing and information practices in the natural sciences.- Subject-specific information retrieval tools, e. g. classifications and thesauri.- New web-based information and communication technologies.- Searching for subject-specific facts (e. g. substances and physical data).- Information search skills for the workplace.- Copyright and citations.- Electronic publishing. Some sessions will focus on particular disciplines (wherever possible, on disciplines inthe natural sciences).
Intended learning outcomes
Students have developed a differentiated understanding of the publishing and information practices in their dis-cipline and are familiar with the possibilities offered by electronic publishing. They are able to use electronictools to locate subject-specific facts in a variety of resources. Students are able to work with subject-specific in-formation retrieval tools as well as to use new web-based technologies to share information. They have develo-ped an understanding of the legal framework surrounding publications, information, and communication in anacademic context and are able to use information responsibly.
Courses (type, number of weekly contact hours, language — if other than German)
Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 60 minutes) or b) preparing and delivering a presentation with slides (approx.10 minutes or approx. 5 minutes and approx. 1 page) or c) completing exercises (approx. 10 exercises) or d) pre-sentation without slides (approx. 20 to 30 minutes) or e) preparing and delivering a presentation with slides (ap-prox. 5 minutes) and completing exercises (approx. 5 exercises) or f) presentation without slides (approx. 10 to15 minutes) and completing exercises (approx. 5 exercises)
Allocation of places
Number of places: 10 to 50. There is a restricted number of places. If necessary, places will be allocated as fol-lows: Students of the degree programmes of the respective subject-specific focuses will be given preferenti-al consideration. The remaining places, if and when any become available, will be allocated to students of theother natural sciences degree programmes. In each of the above-mentioned groups, 30% of places will be allo-cated according to the number of subject semesters. Among applicants with the same number of subject seme-sters, places will be allocated by lot. The remaining 70% of places will each be allocated by lot.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationApplied Superconduction 11-ASL-092-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
German contents available but not translated yet. Physikalische Grundlagen der Supraleitung. Anwendungen in der Energietechnik. Apparative Entwicklungen. Me-thoden der Materialwissenschaften zur Berechnung von Temperaturprofilen in Supraleitern
Intended learning outcomes
German intended learning outcomes available but not translated yet. Die Studierenden verfügen über ein Grundverständnis der Supraleitung als ein makroskopisch beobachtbaresQuantenphänomen. Sie sind in der Lage, in Grundzügen die Beiträge der Materialwissenschaften zur Weiterent-wicklung der Supraleitung zu beurteilen. Sie haben die Fähigkeit, Fragen zur Supraleitung wissenschaftlich zudiskutieren und energietechnische Entwicklungen kritisch zu hinterfragen. Sie sind ferner in der Lage, praktischeFragestellungen mathematisch zu behandeln.
Courses (type, number of weekly contact hours, language — if other than German)
R + V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examinationin groups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) orc) project report (approx. 8 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation (ap-prox. 30 minutes)Assessment offered: once a year, winter semesterLanguage of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationPrinciples of Energy Technologies 11-ENT-092-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
German contents available but not translated yet. Physikalische Grundlagen von Energiekonservierung und Energiewandlung, Energietransport und -Speicherungsowie der regenerativen Energiequellen. Dabei werden auch Aspekte der Materialoptimierung (z.B. nanostruktu-rierte Dämmstoffe, selektive Schichten, hochaktivierte Kohlenstoffe) behandelt. Die Veranstaltung ist insbeson-dere auch für Lehramtsstudenten geeignet. Energy Conservation via Thermal Insulation. Thermodynamic EnergyEfficiency. Fossil Fired Energy Converters. Nuclear Power Plants. Hydroelectricity. Wind Turbines. Photovoltaics.Solar Thermal: Heat. Solar Thermal: Electricity. Biomass. Geothermal Energy. Energy Storage. Energy Transport
Intended learning outcomes
German intended learning outcomes available but not translated yet. Der/Die Studierende kennt die Grundlagen verschiedener Methoden der Energietechnik, insbesondere Ener-gieumwandlung, -transport und Speicherung. Er/Sie überblickt den Aufbau der entsprechenden Anlagen undkann sie vergleichend beurteilen.
Courses (type, number of weekly contact hours, language — if other than German)
R + V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationIntroduction to Plasmaphysics 11-EPP-092-m01
Module coordinator Module offered by
Managing Director of the Institute of Theoretical Physicsand Astrophysics
Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
Plasma Astrophysics: Dynamics of charged particles in electric and magnetic fields, Magnetohydrodynamics,Transport equations for energetic particles, Properties of magnetic turbulence, Propagation of solar particles wi-thin the solar wind, Particle acceleration via shock waves and via interaction with plasma turbulence, Particle ac-celeration and transport in galaxies and other astrophysical objects, Cosmic radiation.
Intended learning outcomes
Knowledge of fundamental processes in plasma astrophysics.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationSemiconductor Lasers - Principles and Current Research 11-HLF-092-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
German contents available but not translated yet. Die Vorlesung vermittelt die Grundlagen der Laserphysik am Beispiel von Halbleiterlasern und geht auf aktuelleBauelemententwicklungen ein. Die Grundlagen von Lasern werden zunächst anhand eines allgemeinen Lasermo-dells beschrieben, das dann um spezielle Aspekte von Halbleiterlasern erweitert wird. Grundlegende Begriffe wiez.B. Schwellenbedingung, Kennlinie und Lasereffizienz werden anhand von gekoppelten Ratengleichungen fürLadungsträger und Photonen hergeleitet. Weitere Themen der Vorlesung sind optische Prozesse in Halbleitern,Schicht- und Stegwellenleiter, Laserresonatoren, Modenselektion, dynamische Eigenschaften sowie Technologiezur Herstellung von Halbleiterlasern. Den Abschluss der Vorlesung bilden aktuelle Themen der Laserforschungwie z.B. Quantenpunktlaser, Quantenkaskadenlaser, THz -- Laser oder Hochleistungslaser.
Intended learning outcomes
German intended learning outcomes available but not translated yet. Der/Die Studierende verfügt über vertiefte Kenntisse in den Grundalgen der Physik von Halbleiterlasern. Er/Sieist in der Lage, diese auf moderne Fragestellungen anzuwenden und kennt die Anwendungen in der aktuellenEntwicklung von Bauelementen.
Courses (type, number of weekly contact hours, language — if other than German)
R + V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationThermodynamics and Economics 11-TDO-092-m01
Module coordinator Module offered by
Managing Director of the Institute of Theoretical Physicsand Astrophysics
Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
Energy and economic growth, entropy production and emission reduction.Part I describes the role of energy conversion in the development of the universe, the evolution of life and the un-folding of civilization. In nonequilibrium thermodynamics, the entropy production density signifies the importan-ce of the second law of thermodynamics for ecological damage and resource consumption. Energy conversion,entropy production and natural resources define the technological and ecological boundaries of industrial eco-nomic growth.Part 2 analyses how the factors capital, work, energy and creativity produce the goods and services of a nationaleconomy and determine the economic growth. In doing so it turns out that the productive power of cheap ener-gy by far exceeds that of expensive labor. Within the current system of taxes and social security contributionsthis discrepancy between power and cost of production factors leads to job cuts, waste of resources, impoveris-hment of the nation states and growing social tensions. It is discussed how Factor income taxes can counteractthis development.Part 3 treats, also in the form of seminar presentations, the techniques of rational use of energy and of the use ofnon-fossile energy sources, and introduces into the optimization program deeco (Dynamic Energy, Emission andCost Optimization).
Intended learning outcomes
In-depth understanding of how energy conversion and entropy production will co-determine the future economicand social development of the world. Comprehension of the relations between thermodynamics and economyand the description of the productive physical basis of modern economical systems as extension of economictheory. The ability to apply the learned knowledge to particular problems. NOTE: this is the module that was run by Prof. Dr. R. Kümmel, tailored on his own theory of economy. Meanwhilehe is retired. So the question would be whether we continue to offer this module or to remove it entirely.
Courses (type, number of weekly contact hours, language — if other than German)
R + V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationSolid State Physics 2 11-FK2-092-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)8 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
1. Electrons in a periodic potential -- the band structurea. Electrical and thermal transportb. Bloch theoremc. Electrons2. Semi-classical models of dynamic processesa. Electrical transport in partially and completely filled bandsb. Fermi surfaces; measurement techniquesc. Electrical transport in external magnetic fieldsd. Boltzmann-equations of transport3. The dielectric function and ferroelectricsa. Macroscopic electrodynamics and microscopic theoryb. Polarizability of solids, of lattices, of valence electrons and quasi-free electrons; optical phonons, polaritons,plasmons, inter-band transitions, Wannier-Mott excitonsc. Ferromagnetism4. Semiconductorsa. Characteristicsb. Intrinsic semiconductorsc. Doped semiconductorsd. Physics and applications of p-n junctionse. Heterostructures5. Magnetisma. Atomic dia- and paramagnetismb. Dia- and paramagnetism in metalsc. Ferromagnetism6. Superconductivitya. Phenomenab. Models of superconductivityc. Tunnel experiments und applications
Intended learning outcomes
Knowledge of effects, concepts and models in advanced solid state physics. Familiarity with the theoretical prin-ciples and with applications of experimental methods.
Courses (type, number of weekly contact hours, language — if other than German)
R + V (no information on SWS (weekly contact hours) and course language available)
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationSolid State Spectroscopy 11-FKS-092-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
Single and many particle picture of electrons in solids. Light-matter interaction. Optical spectroscopy. Electronspectroscopy. X-ray spectroscopies.
Intended learning outcomes
Specific and in-depth knowledge of solid-sate spectroscopy. Knowledge of different methods of spectrosco-py and their applications. Understanding of the theoretical principles and modern developments in the relatedscience.
Courses (type, number of weekly contact hours, language — if other than German)
R + V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationSemiconductor Physics 11-HLP-092-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
German contents available but not translated yet. vertiefte Behandlung der Kristallbindung und elektronischen Bandstruktur in Halbleitern. optische Anregungenund deren Kopplungseffekte. Elektron-Phonon-Kopplung. Temperaturabhängige Transporteigenschaften. Quanti-sierungseffekte in Halbleitern mit reduzierten Dimensionen. (semi-)magnetische Halbleiter
Intended learning outcomes
German intended learning outcomes available but not translated yet. Der/Die Studierende verfügt über spezifisches, vertieftes Wissen im Fachgebiet Halbleiterphysik. Er/Sie kenntdie physikalischen Grundlagen der Halbleiter und hat einen Überlick über wichtige Eigenschaften von halbleiten-den Materialien.
Courses (type, number of weekly contact hours, language — if other than German)
R + V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationSemiconductor Nanostructures 11-HNS-092-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
Semiconductor Nanostructures are frequently referred to as "artificial materials". In contrast to atoms, moleculesor macroscopic crystals, their electronic, optical and magnetic properties can be systematically tailored via chan-ging their size. The lecture addresses technological challenges in the preparation of semiconductor nanostruc-tures of varying dimensions (2D, 1D, 0D). It provides the basic theoretical concepts to describe their properties,with a focus on optical properties and light-matter coupling. Moreover, it discusses the challenges and conceptsof novel optoelectronic and quantum photonic devices based on such nanostructures, including building blocksfor quantum communication and quantum computing architectures.
Intended learning outcomes
Familiarity with the fundamental properties of semiconductor nanostructures as well as with their theoreticalfoundations. Knowledge of the technological methods to fabricate such structures, and of their applications tonovel photonic devices.
Courses (type, number of weekly contact hours, language — if other than German)
R + V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationMagnetism 11-MAG-092-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
Dia- and paramagnetism, Exchange interaction, Ferromagnetism, Antiferromagnetism, Anisotropy, Domain struc-ture, Nanomagnetism, Superparamagnetism, Experimental methods to measure magnetic properties, Kondo ef-fect.
Intended learning outcomes
Knowledge of the basic terminology, concepts and phenomena of magnetism and the experimental methods tomeasure them. Skills in constructing simple models and describing the mathematical formalism, and the abilityto apply these skills to the mentioned fields of magnetism. Competence to independently solve problems in the-se fields. Capability of assessing the precision of observations and of their analysis.
Courses (type, number of weekly contact hours, language — if other than German)
R + V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 58 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationNanoanalytics 11-NAN-092-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
German contents available but not translated yet. Grundlagen der analytischen Verfahren im Bereich der Nanostrukturphysik, bildgebende Verfahren zur Mikrosko-pie bis zur atomaren Skala, Untersuchung der chemischen Komposition, Spektroskopie der elektronischen Ei-genschaften, Nutzung von Röntgenmethoden. - Physik und Materialsysteme auf der Nanoskala. - Rastersonden:Rasterkraftmikroskopie. Rastertunnelmikroskopie. - Elektronensonden: Rasterelektronenmikroskop. Transmis-sions-Elektronenmikroskop. - Sekundärionen-Massenspektrometrie. - Röntgenmethoden: Synchrotron-Spektro-skopie. Photoemission. Röntgenabsorption
Intended learning outcomes
German intended learning outcomes available but not translated yet. Die Studierenden verfügen über wesentliche Kenntnisse über moderne Untersuchungsmethoden für verschie-dene Nanostrukturen bis hinunter zur atomaren Skala. Sie kennen Mikroskopieverfahren, dier in der Labor- undIndustriepraxis verwendet werden und spektroskopische Methoden zur Bestimmung von elektronischen Eigen-schaften. Sie sind in der Lage, die Leistungsfähigkeit verschiedener Untersuchungsmethoden zu beurteilen.
Courses (type, number of weekly contact hours, language — if other than German)
R + V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 59 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationLow-Dimensional Structures 11-NDS-092-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)4 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
Symmetry of crystal latticesLattice dynamics and growth techniques of low-dimensional structuresX-Ray diffractionMolecular beam epitaxy
Intended learning outcomes
Familiarity with the basic principles of the crystal growth of low-dimensional structures and the techniques fortheir preparation and their characterization. Knowledge of the bandstructure of the most important semiconduc-tors, the fabrication of semiconductor heterostructures as well as MOS-diodes and their properties. Familiaritywith the subband-structure of semiconductor heterostructures and MOS-diodes and can judge on the importan-ce of many body effects. Ability to solve problems related to potentials in one dimension by applying Poisson'sequation. Knowledge of k*p theory, the 2D subband structure from the bulk bandstructure, the meaning of mo-dulation doping and are familiarity with the 2D hydrogen atom. Understanding of how an external magnetic fieldacts on the properties of a free electron gas in 2D. Basic knowledge of the meaning of a gauge, Landau-quantiza-tion, filling factor and Landau degeneracy. Understanding of the dependence of various physical properties onthe filling factor, and ability solve implicit problems via numerical methods. Familiarity with the elementary exci-tations in two-dimensional systems.
Courses (type, number of weekly contact hours, language — if other than German)
R + V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 62 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationNano-Optics 11-NOP-092-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)4 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
The lecture conveys theoretical fundamentals, experimental techniques, and applications of nano-optics startingfrom the discussion of the focusing of light. Based on this, the fundamentals of modern far-field optical micros-copy are discussed. In the following, the near-field optical microscopy is introduced and discussed. As a furtherbasis, quantum emitters are introduced and their light emission in nano-environments is derived. Plasmons in2D, 1D and 0 dimensions are introduced and discussed in detail. This finally leads to the concept of optical an-tennas.
Intended learning outcomes
Specific and in-depth knowledge of the topic of nano-optics. Familiarity with the basic theoretical descriptionand applications of nano-optics as well as the current developments of the topic.
Courses (type, number of weekly contact hours, language — if other than German)
R + V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 63 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationQuantum Mechanics II 11-QM2-092-m01
Module coordinator Module offered by
Managing Director of the Institute of Theoretical Physicsand Astrophysics
Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)8 numerical grade --
Duration Module level Other prerequisites1 semester undergraduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
"Quantum mechanics II" constitutes the central theoretical course to be taken within the international Master'sprogram in physics. While the specific emphasis can be adjusted individually, the core topics that are supposedto be covered should include:1. Second quantization: fermions and bosons2. Band structures of particles in a crystal3. Angular momentum, symmetry operators, Lie Algebras4. Scattering theory: potential scattering, partial wave expansion5. Relativistic quantum mechanics: Klein-Gordon equation, Dirac equation, Lorentz group, fine structure splittingof atomic spectra6. Quantum entanglement7. Canonical formalism
Intended learning outcomes
In-depth knowledge of advanced quantum mechanics. Thorough understanding of the mathematical and theore-tical concepts of the listed topics. Ability to describe or model problems of modern theoretical quantum physicsmathematically, to solve problems analytically or using approximation methods and to interpret the results phy-sically. The course is pivotal to subsequent theory courses in astrophysics, high energy physics and condensedmatter / solid state physics. The course is mandatory for all Master's students.
Courses (type, number of weekly contact hours, language — if other than German)
R + V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 64 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 65 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationQuantum Phenomena in electronic correlelated Materials 11-QPM-092-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
German contents available but not translated yet. Quanteneffekte und -phänomene in der aktuellen Festkörperforschung. Korrelationen. Freies Elektronengas undFermiflüssigkeit. Stark korrelierte Systeme
Intended learning outcomes
German intended learning outcomes available but not translated yet. Der/Die Studierende verfügt über spezifisches, vertieftes Wissen über aktuelle Forschung in der Festkörperphy-sik, insbesondere über Quanteneffekte in stark korrelierten Systemen. Er/Sie kann den Zusammenhang zwi-schen der theoretischen Beschreibung solcher Systeme und den aktuellen experimentellen Resultaten herstel-len.
Courses (type, number of weekly contact hours, language — if other than German)
R + V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 66 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationMany Body Quantum Theory 11-QVTP-092-m01
Module coordinator Module offered by
Managing Director of the Institute of Theoretical Physicsand Astrophysics
Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)8 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
This will usually be a course on quantum many particle physics approached by the perturbative methods usingGreen's functions.An outline could be: 1 Single-particle Green's function2 Review of second quantization3 Diagrammatic method using many particle Green's functions at temperature T=04 Diagrammatic method for finite T5 Landau theory of Fermi liquids6 Superconductivity7 One-dimensional systems and bosonization
Intended learning outcomes
Working knowledge of the methods of quantum field theory in a non-relativistic context. Ability to study proper-ties of Fermi liquids (and bosonic systems) beyond the one-particle picture. Acquisition of methods which are es-sential for the understanding the effects of interactions, including superconductivity and the Kondo effect.
Courses (type, number of weekly contact hours, language — if other than German)
R + V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 67 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 68 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationRelativistic Effects in Mesoscopic Systems 11-RMS-092-m01
Module coordinator Module offered by
Managing Director of the Institute of Theoretical Physicsand Astrophysics
Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)5 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
German contents available but not translated yet. Relativistische Effekte in Mesoskopischen Systemen. - Spin-Bahn-Kopplung. - Dirac-Gleichung. - Quantenhallef-fekt. - Topologische Isolatoren. - Majorana-Fermionen
Intended learning outcomes
German intended learning outcomes available but not translated yet. Die Studierenden beherrschen die mathematischen Methoden zur Beschreibung relativistischer Quantensyste-me, insbesondere im Bereich der mesoskopischen Physik. Sie sind in der Lage, ihre Kenntnisse auf einfache Sy-steme anzuwenden.
Courses (type, number of weekly contact hours, language — if other than German)
R + V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationTheoretical Solid State Physics 11-TFK-092-m01
Module coordinator Module offered by
Managing Director of the Institute of Theoretical Physicsand Astrophysics
Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)8 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
The contents of this two-term course will depend on the choice of the lecturer, and may include parts of the sylla-bus which could alternatively be offered as "Quantum Many Body Physics" (11-QVTP).A possible syllabus may be:1 Band structure (Sommerfeld theory of metals, Bloch theorem, k.p approach and effective Hamiltonians for to-pological insulators (TIs), bulk-surface correspondence, general properties of TIs)2 Electron-electron interactions in solids (path integral method for weakly interacting fermions, mean field theo-ry, random phase approximation (RPA), density functional theory)3 Application of mean field theory and the RPA to magnetism4 BCS theory of superconductivity
Intended learning outcomes
In-depth knowledge of the topics listed above. In-depth understanding of the concepts involved and ability toapply the methods listed. This provides a thorough working knowledge of a large number of topics treated in thestandard textbooks on theoretical solid state physics.
Courses (type, number of weekly contact hours, language — if other than German)
R + V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 70 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Referred to in LPO I (examination regulations for teaching-degree programmes)
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Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 71 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationTheory of Superconduction 11-TSL-092-m01
Module coordinator Module offered by
Managing Director of the Institute of Theoretical Physicsand Astrophysics
Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)5 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
Overview of the phenomenology of conventional and nconventional superconductivity. Empirical Matthias's ru-les for superconductivity. Review of BCS theory and critical discussion of its applicability for different types ofsuperconductors. Extension of the phenomenological Ginzburg-Landau theory to a quantum field theory usingFeynman diagrams and functional integrals. Ward identities and response functions. Goldstone modes, phasefluctuations, and coupling to the electromagnetic field. Interpretation of the Meissner effect in terms of the Higgsmechanism. Interplay of magnetism and conventional/unconventional superconductivity. Discussion of currentresearch topics and perspective on room-temperature superconductivity.
Intended learning outcomes
Profound understanding of unconventional superconductivity and its interplay with magnetism in the context ofcurrent research. Knowledge of BCS mean-field theory, the quantum-field theory methods necessary to extendBCS theory, as well as the Meissner effect and the Higgs mechanism. Basic understanding of unconventional su-perconductors and their fascinating connection with competing magnetic phases.
Courses (type, number of weekly contact hours, language — if other than German)
R + V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationBiophysical Measurement Technology in Medical Science 11-BMT-092-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
German contents available but not translated yet. Gegenstand der Vorlesung sind die physikalischen Grundlagen bildgebender Verfahren und deren Anwendung inder Biomedizin. Schwerpunkte bilden die konventionelle Röntgentechnik, die Computertomographie, bildgeben-de Verfahren der Nuklearmedizin, der Ultraschall und die MR-Tomographie. Abgerundet wird diese Vorlesung mitder Systemtheorie abbildender Systeme und mit einem Ausflug in die digitale Bildverarbeitung.
Intended learning outcomes
German intended learning outcomes available but not translated yet. Die Studierenden kennen die physikalischen Grundlagen bildgebender Verfahren und deren Anwendung in derBiomedizin. Sie verstehen die Prinzipien der Bildentstehung und sind in der Lage, die verschiedenen Verfahrenzu erläutern und einfache Bilder zu interpretieren.
Courses (type, number of weekly contact hours, language — if other than German)
R + V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
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Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 73 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationLaboratory and Measurement Technology in Biophysics 11-LMB-092-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
German contents available but not translated yet. Gegenstand der Vorlesung sind relevante Grundlagen der Molekular- und Zellbiologie sowie die physikali-schen Grundlagen biophysikalischer Verfahren zur Untersuchung und Manipulation von biologischen Systemen.Schwerpunkte bilden optische Messtechniken und Sensorik, Verfahren der Einzelteilchendetektion, spezielle Mi-kroskopietechniken, sowie Verfahren zur Strukturaufklärung von Biomolekülen.
Intended learning outcomes
German intended learning outcomes available but not translated yet. Die Studierenden kennen die Grundlagen der Molekular- und Zellbiologie sowie die physikalischen Grundla-gen biophysikalischer Verfahren zur Untersuchung und Manipulation von biologischen Systemen. Sie verfügenüber Kenntnisse optischer Meßtechniken und deren Anwendungen und sind in der Lage, die Verfahren der Struk-turaufklärung auf einfache Biomoleküle anzuwenden.
Courses (type, number of weekly contact hours, language — if other than German)
R + V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationPhysics of Complex Systems 11-PKS-092-m01
Module coordinator Module offered by
Managing Director of the Institute of Theoretical Physicsand Astrophysics
Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
1. Theory of critical phenomena in thermal equilibriumt2. Introduction into the physics out of equilibriumt3. Entropy production and fluctuationst4. Phase transitions away from equilibriumt5. Universalityt6. Spin glassest7. Theory of neural networks
Intended learning outcomes
In-depth knowledge of concepts and methods essential for a thorough understanding of collective phenome-na in complex many-body systems. Thorough understanding of the concepts of entropy, entropy production anduniversality. Ability to appreciate the central importance of symmetries. Ability to perform research tasks in thefield of complex systems.
Courses (type, number of weekly contact hours, language — if other than German)
R + V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationQuantum Information and Quantum Computing 11-QIC-092-m01
Module coordinator Module offered by
Managing Director of the Institute of Theoretical Physicsand Astrophysics
Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)5 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
1. Brief summary of classical information theory2. Quantum theory seen from the perspective of information theory3. Composite systems and the Schmidt decomposition4. Entanglement measures5. Quantum operations, POVMs, and the theorems of Kraus and Stinespring6. Quantum gates and quantum computers7. Elements of the theory of decoherence
Intended learning outcomes
Comprehensive understanding of quantum states and identity matrix beyond the usual textbook interpretation.Knowledge of handling tensor products and dealing with quantum effects in multipartite quantum systems. In-depth understanding of the phenomenon of entanglement. Knowledge of the fundamental mathematical con-cepts of quantum information theory. Ability to assess the limitations of quantum computing arising from deco-herence.
Courses (type, number of weekly contact hours, language — if other than German)
R + V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
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Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 76 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 77 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationStatistics, Data Analysis and Computer Physics 11-SDC-092-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)4 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
Statistics, data analysis and computer physics.
Intended learning outcomes
German intended learning outcomes available but not translated yet. Der/Die Studierende verfügt über spezifisches, vertieftes Wissen im Fachgebiet Statistik, Datenanalyse undComputerphysik.
Courses (type, number of weekly contact hours, language — if other than German)
R + V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 78 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationProgramming of Distributed Systems 10-I=PVS-102-m01
Module coordinator Module offered by
holder of the Chair of Computer Science II Institute of Computer Science
ECTS Method of grading Only after succ. compl. of module(s)8 numerical grade --
Duration Module level Other prerequisites1 semester graduate Where applicable, prerequisites as specified by the lecturer at the begin-
ning of the course (e. g. completion of exercises).
Contents
Design and development of parallely and distributedly executed programs.
Intended learning outcomes
The students possess the methodic knowledge and practical skills for the design and development of parallelyand distributedly running programs.
Courses (type, number of weekly contact hours, language — if other than German)
V + Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
written examination (approx. 80 to 90 minutes). If announced by the lecturer by four weeks prior to the examina-tion date, the written examination can be replaced by an oral examination of one candidate each or an oral ex-amination in groups. A 80 to 90 minute written examination is equivalent to a 20 minute (approx.) oral examina-tion of one candidate each, a 30 minute (approx.) oral examination in groups of 2 and a 40 minute (approx.) oralexamination in groups of 3.Language of assessment: German, English if agreed upon with the examiner
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 79 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationArtificial Intelligence 10-I=KI-102-m01
Module coordinator Module offered by
holder of the Chair of Computer Science VI Institute of Computer Science
ECTS Method of grading Only after succ. compl. of module(s)8 numerical grade --
Duration Module level Other prerequisites1 semester graduate Where applicable, prerequisites as specified by the lecturer at the begin-
ning of the course (e. g. completion of exercises).
Contents
Intelligent agents, uninformed and heuristic search, constraint problem solving, search with partial information,propositional and predicate logic and inference, knowledge representation, planning, probabilistic closure andBayesian networks, utility theory and decidability problems, learning from observations, knowledge while lear-ning, neural networks and statistical learning methods, reinforcement learning.
Intended learning outcomes
The students possess theoretical and practical knowledge about artificial intelligence and are able to assesspossibilities for its application.
Courses (type, number of weekly contact hours, language — if other than German)
V + Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
written examination (approx. 80 to 90 minutes); if announced by the lecturer by four weeks prior to the examina-tion date, the written examination can be replaced by an oral examination of one candidate each or an oral ex-amination in groups (one candidate each: 15 minutes, groups of 2: 20 minutes, groups of 3: 25 minutes)Language of assessment: German, English if agreed upon with the examiner
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 80 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationDatabases II 10-I=DB2-102-m01
Module coordinator Module offered by
Dean of Studies Informatik (Computer Science) Institute of Computer Science
ECTS Method of grading Only after succ. compl. of module(s)5 numerical grade --
Duration Module level Other prerequisites1 semester graduate Where applicable, prerequisites as specified by the lecturer at the begin-
ning of the course (e. g. completion of exercises).
Contents
Data warehouses and data mining; XML databases; web databases;introduction to Datalog.
Intended learning outcomes
The students have advanced knowledge about relational databases, XML and data mining.
Courses (type, number of weekly contact hours, language — if other than German)
V + Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
written examination (approx. 50 to 60 minutes); if announced by the lecturer by four weeks prior to the examina-tion date, the written examination can be replaced by an oral examination of one candidate each or an oral ex-amination in groups (one candidate each: 15 minutes, groups of 2: 20 minutes, groups of 3: 25 minutes)Language of assessment: German, English if agreed upon with the examiner
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 81 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationProgram Design and Analysis 10-I=PA-102-m01
Module coordinator Module offered by
holder of the Chair of Computer Science II Institute of Computer Science
ECTS Method of grading Only after succ. compl. of module(s)5 numerical grade --
Duration Module level Other prerequisites1 semester graduate Where applicable, prerequisites as specified by the lecturer at the begin-
ning of the course (e. g. completion of exercises).
Contents
Program analysis, model creation in software engineering, program quality, test of programs, process models.
Intended learning outcomes
The students are able to analyse programs, to use testing frameworks and metrics as well as to judge programquality.
Courses (type, number of weekly contact hours, language — if other than German)
V + Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
written examination (approx. 50 to 60 minutes); if announced by the lecturer by four weeks prior to the examina-tion date, the written examination can be replaced by an oral examination of one candidate each or an oral ex-amination in groups (one candidate each: 15 minutes, groups of 2: 20 minutes, groups of 3: 25 minutes)Language of assessment: German, English if agreed upon with the examiner
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 82 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationApplied Analysis 10-M=AAAN-102-m01
Module coordinator Module offered by
Dean of Studies Mathematik (Mathematics) Institute of Mathematics
ECTS Method of grading Only after succ. compl. of module(s)10 numerical grade --
Duration Module level Other prerequisites1 semester graduate Registration for the exercise must be made via SB@home at the begin-
ning of the course or as announced by the lecturer in accordance withthe specified registration deadlines. Certain prerequisites must be metto qualify for admission to assessment (e. g. successful completion of acertain percentage of exercises). The lecturer will inform students aboutthe respective details at the beginning of the course. Registration for theexercise will be considered a declaration of will to seek admission to as-sessment. If students have obtained the qualification for admission toassessment over the course of the semester, the lecturer will put their re-gistration for assessment into effect. Students who meet all prerequisiteswill be admitted to assessment in the current or in the subsequent seme-ster. For assessment at a later date, students will have to obtain the qua-lification for admission to assessment anew.
Contents
In-depth study of functional analysis and operator theory, Sobolev spaces and partial differential equations,theory of Hilbert spaces and Fourier analysis, spectral theory and quantum mechanics, numerical methods (inparticular FEM methods), principles of functional analysis, function spaces, embedding theorems, compactness,theory of elliptic, parabolic and hyperbolic partial differential equations with methods from functional analysis.
Intended learning outcomes
The student is acquainted with the fundamental notions, methods and results of higher analysis. He/She is ableto establish a connection between his/her acquired skills and other branches of mathematics and questions inphysics and other natural and engineering sciences.
Courses (type, number of weekly contact hours, language — if other than German)
V + Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
At the beginning of the course, the lecturer will choose one of the following methods of assessment: a) writtenexamination (90 to 120 minutes), b) oral examination of one candidate each (approx. 20 minutes), c) oral exami-nation in groups (groups of 2, approx. 30 minutes)Assessment offered: Assessment offered in the semester in which the course is offered and in the subsequentsemester, course offered on demand or every four semesters.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 83 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationComplex Analysis 10-M=AFTH-102-m01
Module coordinator Module offered by
Dean of Studies Mathematik (Mathematics) Institute of Mathematics
ECTS Method of grading Only after succ. compl. of module(s)10 numerical grade --
Duration Module level Other prerequisites1 semester graduate Registration for the exercise must be made via SB@home at the begin-
ning of the course or as announced by the lecturer in accordance withthe specified registration deadlines. Certain prerequisites must be metto qualify for admission to assessment (e. g. successful completion of acertain percentage of exercises). The lecturer will inform students aboutthe respective details at the beginning of the course. Registration for theexercise will be considered a declaration of will to seek admission to as-sessment. If students have obtained the qualification for admission toassessment over the course of the semester, the lecturer will put their re-gistration for assessment into effect. Students who meet all prerequisiteswill be admitted to assessment in the current or in the subsequent seme-ster. For assessment at a later date, students will have to obtain the qua-lification for admission to assessment anew.
Contents
In-depth study of mapping properties of analytic functions and their generalisations with modern analytic andgeometric methods. Structural properties of families of holomorphic and meromorphic functions. Special functi-ons (e. g. elliptic functions).
Intended learning outcomes
The student is acquainted with the fundamental notions, methods and results of higher complex analysis, in par-ticular the (geometric) mapping properties of holomorphic functions. He/She is able to establish a connectionbetween his/her acquired skills and other branches of mathematics and applications in other subjects.
Courses (type, number of weekly contact hours, language — if other than German)
V + Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
At the beginning of the course, the lecturer will choose one of the following methods of assessment: a) writtenexamination (90 to 120 minutes), b) oral examination of one candidate each (approx. 20 minutes), c) oral exami-nation in groups (groups of 2, approx. 30 minutes)Assessment offered: Assessment offered in the semester in which the course is offered and in the subsequentsemester, course offered on demand or every four semesters.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 84 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationGroups and their Representations 10-M=VGDS-102-m01
Module coordinator Module offered by
Dean of Studies Mathematik (Mathematics) Institute of Mathematics
ECTS Method of grading Only after succ. compl. of module(s)10 numerical grade --
Duration Module level Other prerequisites1 semester graduate Registration for the exercise must be made via SB@home at the begin-
ning of the course or as announced by the lecturer in accordance withthe specified registration deadlines. Certain prerequisites must be metto qualify for admission to assessment (e. g. successful completion of acertain percentage of exercises). The lecturer will inform students aboutthe respective details at the beginning of the course. Registration for theexercise will be considered a declaration of will to seek admission to as-sessment. If students have obtained the qualification for admission toassessment over the course of the semester, the lecturer will put their re-gistration for assessment into effect. Students who meet all prerequisiteswill be admitted to assessment in the current or in the subsequent seme-ster. For assessment at a later date, students will have to obtain the qua-lification for admission to assessment anew.
Contents
Finite permutation groups and character theory of finite groups, interrelations and special techniques such asthe S-rings of Schur.
Intended learning outcomes
The student masters advanced algebraic concepts and methods. He/She gains the ability to work on contempo-rary research questions in group theory and representation theory and can apply his/her skills to complex pro-blems.
Courses (type, number of weekly contact hours, language — if other than German)
V + Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
At the beginning of the course, the lecturer will choose one of the following methods of assessment: a) writtenexamination (approx. 90 to 120 minutes; usually chosen), b) oral examination of one candidate each (approx. 20minutes), c) oral examination in groups of 2 candidates (approx. 30 minutes total)Assessment offered: Assessment offered in the semester in which the course is offered and in the subsequentsemester, course offered on demand or every four semesters.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationNumeric of Partial Differential Equations 10-M=VNPE-102-m01
Module coordinator Module offered by
Dean of Studies Mathematik (Mathematics) Institute of Mathematics
ECTS Method of grading Only after succ. compl. of module(s)10 numerical grade --
Duration Module level Other prerequisites1 semester graduate Registration for the exercise must be made via SB@home at the begin-
ning of the course or as announced by the lecturer in accordance withthe specified registration deadlines. Certain prerequisites must be metto qualify for admission to assessment (e. g. successful completion of acertain percentage of exercises). The lecturer will inform students aboutthe respective details at the beginning of the course. Registration for theexercise will be considered a declaration of will to seek admission to as-sessment. If students have obtained the qualification for admission toassessment over the course of the semester, the lecturer will put their re-gistration for assessment into effect. Students who meet all prerequisiteswill be admitted to assessment in the current or in the subsequent seme-ster. For assessment at a later date, students will have to obtain the qua-lification for admission to assessment anew.
Contents
Types of partial differential equations, qualitative properties, finite differences, finite elements, error estimates(numerical methods for elliptic, parabolic and hyperbolic partial differential equations; finite elements method,discontinuous Gelerkin finite elements method, finite differences and finite volume methods).
Intended learning outcomes
The student is acquainted with advanced methods for discretising partial differential equations.
Courses (type, number of weekly contact hours, language — if other than German)
V + Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
At the beginning of the course, the lecturer will choose one of the following methods of assessment: a) writtenexamination (90 to 120 minutes), b) oral examination of one candidate each (approx. 20 minutes), c) oral exami-nation in groups (groups of 2, approx. 30 minutes)Assessment offered: Assessment offered in the semester in which the course is offered and in the subsequentsemester, course offered on demand or every four semesters.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationQuantum Control and Quantum Computing 10-M=VQKC-102-m01
Module coordinator Module offered by
Dean of Studies Mathematik (Mathematics) Institute of Mathematics
ECTS Method of grading Only after succ. compl. of module(s)5 numerical grade --
Duration Module level Other prerequisites1 semester graduate Registration for the exercise must be made via SB@home at the begin-
ning of the course or as announced by the lecturer in accordance withthe specified registration deadlines. Certain prerequisites must be metto qualify for admission to assessment (e. g. successful completion of acertain percentage of exercises). The lecturer will inform students aboutthe respective details at the beginning of the course. Registration for theexercise will be considered a declaration of will to seek admission to as-sessment. If students have obtained the qualification for admission toassessment over the course of the semester, the lecturer will put their re-gistration for assessment into effect. Students who meet all prerequisiteswill be admitted to assessment in the current or in the subsequent seme-ster. For assessment at a later date, students will have to obtain the qua-lification for admission to assessment anew.
Contents
Basics in dynamics of quantum-mechanical systems (e. g. density operators, observables, Schrödinger equation,Liouville-von-Neumann equation), bilinear control systems in quantum mechanics (e. g. finite-dimensional spinsystems and/or infinite-dimensional Schrödinger equations with external control), applications (e. g. in quantumcomputing or magnetic resonance spectroscopy).
Intended learning outcomes
The student is acquainted with advanced methods in quantum-mechanical control systems. He gains the abilityto work on contemporary research questions in and applications of control systems in quantum mechanics.
Courses (type, number of weekly contact hours, language — if other than German)
V + Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
At the beginning of the course, the lecturer will choose one of the following methods of assessment: a) writtenexamination (60 to 90 minutes), b) oral examination of one candidate each (approx. 15 minutes), c) oral exami-nation in groups (groups of 2, approx. 20 minutes)Assessment offered: Assessment offered in the semester in which the course is offered and in the subsequentsemester, course offered on demand or every four semesters.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationElectronics 11-A2-092-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester undergraduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
German contents available but not translated yet. Grundlagen elektronischer Bauelemente und Schaltungen. Analoge Schaltungstechnik: Passive (Widerstände,Kondensatoren, Spulen und Dioden) und aktive Bauelemente (Bipolar- und Feldeffektransistoren sowie Operati-onsverstärker). Digitalen Schaltungen: unterschiedliche Gatter-Typen und CMOS-Schaltungen. Mikrokontroller
Intended learning outcomes
German intended learning outcomes available but not translated yet. Der/Die Studierende verfügt über das Verständnis und die Kenntnisse des praktischen Aufbaus elektronischerSchaltungen aus dem Bereich analoger und digitaler Schaltungstechnik.
Courses (type, number of weekly contact hours, language — if other than German)
V + Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
written examination (approx. 90 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.
Allocation of places
Only as part of pool of general key skills (ASQ): 15 places. Places will be allocated by lot.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationSemiconductor Physics and Devices 11-SPD-102-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
German contents available but not translated yet. Grundlagen der Halbleiterphysik. Einführung in Halbleiter-Schlüsseltechnologien. Bauelemente aus den Berei-chen Elektronik und Photonik
Intended learning outcomes
German intended learning outcomes available but not translated yet. Die Studierenden. - sind mit den Eigenschaften von Halbleitern verstraut, sie haben einen Überblick über dieelektronischen und phononischen Bandstrukturen wichtiger Halbleiter und den daraus ableitbaren elektroni-schen, optischen und thermischen Eigenschaften. - kennen die Grundlagen des Ladungstransports und kön-nen die Poisson-, Boltzmann- und Kontinuitätsgleichung bei der Lösung von Fragestellungen anwenden. - ha-ben einen Einblick in die Methoden der Halbleiterherstellung und sind mit den Ansätzen der Planartechnologieund neueren Entwicklungen auf diesem Sektor vertraut, sie haben ein grundlegendes Verständnis für die Bauele-menteherstellung. - verstehen den Aufbau und die Funktionsweise der wichtigsten Bauelemente aus der Elektro-nik (Diode, Transistor, FET, Thyristor, Diac, Triac), dem Bereich Mikrowellenanwendungen (Tunnel-, Impatt-, Ba-ritt- und Gunn-Diode) und der Optoelektronik (Fotodiode, Solarzelle, Leuchtdiode, Halbleiter-Injektionslaser ). -kennen die Realisierungsmöglichkeiten von niedrigdimensionalen Ladungsträgersystemen auf Halbleiterbasisund ihre technologische Relevanz. - sind mit neueren Entwicklungen auf dem Bauelementesektor vertraut
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
written examination (approx. 90 minutes) or oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or pro-ject report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or presentation/seminar presentation (approx.30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationQuantum Transport in Semiconductor Nanostructures 11-QTH-102-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
The lecture addresses the fundamental transport phenomena of electrons in nanostructures. This includes thetopics of: Ballistic and diffuse transport, Electron interference effects, Quantization of conductivity, Interactionphenomena between electrons, Coulomb blockade, Thermoelectric properties, Description of spin-dependenttransport phenomena, Topological Insulators, Solid-state quantum computers
Intended learning outcomes
Working knowledge of the basics of nanostructure electronics in theory and practice. Working knowledge of thefunctions and applications of the respective components.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationRenormalization Group Methods in Field Theory 11-RMFT-102-m01
Module coordinator Module offered by
Managing Director of the Institute of Theoretical Physicsand Astrophysics
Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
This course is complementary to the discussion of Wilson's renormalizationg group (RG) as covered in the cour-se "Renormalization Group and Critical Phenomena" (11-CRP). This course focuses on the diagrammatic formu-lation of RG flow equations and its relation to diagrammatic perturbation expansions. For interacting fermion sy-stems, this is of particular relevance in the context of the functional renormalization group. A possible outline ofthe course is: 1. Wilson's RG2. Path integral formulation of interacting fermions3. Bethe-Salpeter-equation4. RG flow equations for the one-particle and the two-particle vertex5. Comparison of flow equations with diagrammatic resummation schemes (such as the "random phase approxi-mation")6. RG flow equations for spin systems
Intended learning outcomes
Familiarity with modern diagram based techniques for interacting many-body systems. In-depth understandingof the theoretical framework addressing a range of phenomena in correlated electron systems including super-conductivity, charge and spin density waves, and nematic instabilities.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationSpintronics 11-SPI-102-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
In this lecture, the basic principles of spin transport are taught, with a particular emphasis on the phenomena ofgiant magnetoresistance and tunnel magnetoresistance. New phenomena from the fields of spin dynamics andcurrent-induced spin phenomena are discussed.
Intended learning outcomes
Knowledge of basic principles of spin transport models and of applications of spin transport in information tech-nology. Overview over the state-of-the-art findings in this field (giant magnetoresistance, tunnel magnetoresi-stance).
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationNanotechnology in Energy Research 11-NTE-092-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)4 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
German contents available but not translated yet. Die Nanotechnologie ist im Bereich der Energieforschung von großer Bedeutung. Durch spezielle Funktionsma-terialien ist es möglich die Energieeffizienz in zahlreichen Prozessen oder Anwendungen zu erhöhen. In diesemModul werden speziell Materialien, Oberflächen und Strukturen betrachtet, die aufgrund nanotechnologischerEffekte optimierte Eigenschaften aufweisen. Dabei werden die zugrunde liegenden physikalischen Zusammen-hänge erläutert. Die Betrachtungen finden am Beispiel konkreter Materialien und Komponenten statt, wie bei-spielsweise Wärmedämmstoffe, Wärmespeicher, funktionelle nanoskalige Schicht- und Teilchensysteme mitspektral selektiven Eigenschaften, nanoporöse Vakuumisolationen sowie Elektrodenmaterialien.
Intended learning outcomes
German intended learning outcomes available but not translated yet. Der/Die Studierende verfügt über spezifisches und vertieftes Wissen über die Anwendung der Nanotechnologiein der Energieforschung. Er/Sie kennt Methoden, mit denen die Eigenschaften von Materialien durch Nanotech-nologie beinflusst werden können und die Anwendungen dieser Technologie. Es/sie ist in der Lage, dieses Wis-sen auf spezielle Fragestellungen anzuwenden.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.
Allocation of places
--
Additional information
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationCoating Technologies based on Vapour Deposition 11-BVG-092-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)5 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
German contents available but not translated yet. Physikalisch-technische Grundlagen zu PVD- und CVD-Anlagen und --Prozessen. Schichtabscheidung undSchichtcharakterisierung. Anwendung von Schichtmaterialien im industriellen Massstab.
Intended learning outcomes
German intended learning outcomes available but not translated yet. Der/Die Studierende verfügt über vertiefte Kenntnisse auf dem Gebiet der Schichtabscheidungsprozesse aus derGasphase und erhält Einblicke in deren industrielle Bedeutung und Vielfalt.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationAdvanced Practical Course Master 11-PFM-111-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)10 (not) successfully completed --
Duration Module level Other prerequisites1 semester graduate --
Contents
Foundations of particle, atomic and molecular physics, low-temperature experiments and correlated systems,solid state properties, surfaces and interfaces. Experiments covering the topics x-ray radiation, nuclear magne-tic resonance (NMR), quantum Hall effect, optical pumping and spectroscopy with visible light, Hall effect, super-conductivity, lasers, solid state optics
Intended learning outcomes
German intended learning outcomes available but not translated yet. Der/Die Studierende verfügt über Kenntnisse zur Durchführung eines Experiments, Analyse und Dokumentationder experimentellen Befunde, Grundkenntnisse zur Erstellung einer wissenschaftlichen Veröffentlichung und An-wendung moderner Auswertesysteme. Er/Sie ist mit modernern Experimentierverfahren vertraut. Er/Sie ist in derLage, sich anhand von Publikationen in eine Aufgabenstellung einzuarbeiten, einen Versuch durchzuführen undauszuwerten und seine/ihre Ergebnisse in Form einer wissenschaftlichen Veröffentlichung darzustellen und zudiskutieren.
Courses (type, number of weekly contact hours, language — if other than German)
Prep seminar for Fortgeschrittenen-Praktikum Master (Advanced Practical Course Master): S (1 weekly contacthour)Fortgeschrittenen-Praktikum Master (Advanced Practical Course Master) Part 1: P (3 weekly contact hours), Ger-man or EnglishFortgeschrittenen-Praktikum Master (Advanced Practical Course Master) Part 2: P (3 weekly contact hours), Ger-man or EnglishFortgeschrittenen-Praktikum Master (Advanced Practical Course Master) Part 3: P (3 weekly contact hours), Ger-man or English
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
This module has the following assessment components1. Prep seminar for Fortgeschrittenen-Praktikum Master (Advanced Practical Course Master): oral examination
(approx. 5 to 10 minutes)2. Lab course in part 1 (Fortgeschrittenen-Praktikum Master/Advanced Practical Course Master Part 1): a) Prepa-
ring the experiment will be considered successfully completed if an oral test (approx. 30 minutes) is passedprior to the experiment. b) Performing and evaluating the experiment will be considered successfully comple-ted if a test is passed. Students must prepare an experiment log (approx. 8 pages).
3. Lab course in part 2 (Fortgeschrittenen-Praktikum Master/Advanced Practical Course Master Part 2): a) Prepa-ring the experiment will be considered successfully completed if an oral test (approx. 30 minutes) is passedprior to the experiment. b) Performing and evaluating the experiment will be considered successfully comple-ted if a test is passed. Students must prepare an experiment log (approx. 8 pages).
4. Lab course in part 3 (Fortgeschrittenen-Praktikum Master/Advanced Practical Course Master Part 3): a) Prepa-ring the experiment will be considered successfully completed if an oral test (approx. 30 minutes) is passedprior to the experiment. b) Performing and evaluating the experiment will be considered successfully comple-ted if a test is passed. Students must prepare an experiment log (approx. 8 pages).
Language of assessment: German or EnglishStudents must register for assessment components 1 through 4 online (details to be announced).
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Only those students who have attended the prep seminar for Fortgeschrittenen-Praktikum Master (AdvancedPractical Course Master) will be allowed to perform experiments as part of the courses Fortgeschrittenen-Prakti-kum Master Parts 1 through 3.Students will be offered one opportunity to retake element a) and/or element b) in the respective semester. Topass an assessment component, they must pass both elements (a and b) in the same semester.To pass this module, students must pass each of the assessment components 1 through 4.
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
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Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 99 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationMethods in Surface Spectroscopy 11-MSS-102-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)4 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
German contents available but not translated yet. Experimentelle Randbedingungen: Ultrahochvakuum, Oberflächensensitivität, Licht-Materie-Wechselwirkung,Grundlagen der Photoelektronenspektroskopie (PES), Einteilchenbild der PES, Drei-Stufen-Modell, Vielteilchen-effekte, Linienform, Satelliten, Fermi-Flüssigkeit, Quasi-Teilchen, Beispielsysteme, -spektren, Messungen mitSynchrotronstrahlung, Verwandte experimentelle Methoden
Intended learning outcomes
German intended learning outcomes available but not translated yet. Die Studierenden kennen die physikalischen Grundlagen und experimentellen Methoden der Oberflächenspek-troskopie. Sie sind in der Lage, einfache Messungen vorzunehmen und diese auszuwerten und zu interpretieren.
Courses (type, number of weekly contact hours, language — if other than German)
V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 100 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationCurrent Topics in Experimental Physics 11-EXE6-111-m01
Module coordinator Module offered by
chairperson of examination committee Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Approval by examination committee required.
Contents
Current topics in experimental physics. Credited academic achievements, e.g. in case of change of university orstudy abroad.
Intended learning outcomes
The student posseses advanced knowledge meeting the requirements of a module in experimental physics onMaster's level. He/She commands knowledge in a current field in experimental physics and insight into the mea-suring and evaluation methods which are necessary to acquire this knowledge. He/She is able to classify and tolink the learnt. He/She knows about fields of application.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 120 minutes, for modules with less than 4 ECTS credits approx. 90 minutes; un-less otherwise specified) or b) oral examination of one candidate each or oral examination in groups (approx. 30minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c) project report (ap-prox. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation (approx. 30 minu-tes)Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 101 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationElectron Electron Interaction 11-EEW-102-m01
Module coordinator Module offered by
Managing Director of the Institute of Theoretical Physicsand Astrophysics
Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)4 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
German contents available but not translated yet. 1. Einführung, Systeme, Landauer-Theorie. 2. Wechselwirkendes Elektronengas. 3. 1D Elektronengas (ohne WW).4. Einführung der bosonischen Phasenfelder + WW. 5. Berechnung von Korrelationsfunktionen. 6. Methode derFunktionalintegrale. 7. Renormalisierungsgruppen. 8. Mitberücksichtigung von Spin. 9. Gittermodelle in 1D. 10.Störstelle in einer Luttinger-Flüssigkeit
Intended learning outcomes
German intended learning outcomes available but not translated yet. Die Studierenden kennen die Grundlagen der theoretischen Beschreibung von Elektron-Elektron-Wechselwirkun-gen in einer Dimension.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 102 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationTheoretical Solid State Physics 2 11-TFK2-111-m01
Module coordinator Module offered by
Managing Director of the Institute of Theoretical Physicsand Astrophysics
Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)8 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
A possible continuation of "11-TFK" is the following syllabus:5. Advanced topics of the theory of superconductivity (Bogoliubov-de Gennes equations, effective field theory,Anderson-Higgs description of the Meissner effect)6. Unconventional superconductors (e.G. copper-oxide high-Tc superconductors)7. Green's function methods and Feynman diagrammatic technique8. The Kondo Effect (Anderson's "poor mans scaling", renormalization group)
Intended learning outcomes
Advanced knowledge of the topics listed above. In-depth understanding of both the concepts involved and abili-ty to apply the methods listed. This provides a thorough working knowledge of a large number of topics treatedin the standard textbooks on theoretical solid state physics.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 103 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationCurrent Topics in Theoretical Physics 11-EXT6-111-m01
Module coordinator Module offered by
chairperson of examination committee Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Approval by examination committee required.
Contents
Current topics in theoretical physics. Credited academic achievements, e.g. in case of change of university orstudy abroad.
Intended learning outcomes
The student posseses deepened knowledge meeting the requirements of a module in theoretical physics on Ma-ster's level. He/She commands advanced technical knowledge in a current field in theoretical physics and ma-sters the respective methods. He/She is able to apply these methods to current problems in theoretical physics.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 120 minutes, for modules with less than 4 ECTS credits approx. 90 minutes; un-less otherwise specified) or b) oral examination of one candidate each or oral examination in groups (approx. 30minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c) project report (ap-prox. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation (approx. 30 minu-tes)Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 104 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationUltrafast Spectroscopy and Quantum Control 08-PCM4-PHY-111-m01
Module coordinator Module offered by
lecturer of the seminar "Ultrakurzzeitspektroskopie andQuantenkontrolle"
Institute of Physical and Theoretical Chemistry
ECTS Method of grading Only after succ. compl. of module(s)5 numerical grade --
Duration Module level Other prerequisites1 semester graduate --
Contents
German contents available but not translated yet. Das Modul behandelt spezielle Themen der Ultrakurzzeitspektroskopie und Quantenkontrolle. Schwerpunktesind ultrakurze Laserimpulse, zeitaufgelöste Laserspektroskopie sowie kohärente Kontrolle.
Intended learning outcomes
German intended learning outcomes available but not translated yet. Die Studierenden können die Erzeugung ultrakurze Laserimpulse beschreiben sowie diese selbst charakterisie-ren. Er/Sie kann die zeitaufgelöste Laserspektroskopie theoretisch erklären und experimentelle Methoden an-führen. Er/Sie kann Grundlagen und Anwendungen der Quantenkontrolle darstellen.
Courses (type, number of weekly contact hours, language — if other than German)
S + Ü (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
written examination (90 minutes) or oral examination of one candidate each (20 minutes) or talk (30 minutes)Language of assessment: German or English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 105 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationStructure and Properties of Modern Materials: Experiments and Simulations 08-MW-PHY-111-m01
Module coordinator Module offered by
holder of the Chair of Chemical Technology of Material Syn-thesis
Chair of Chemical Technology of Material Synthesis
ECTS Method of grading Only after succ. compl. of module(s)5 numerical grade --
Duration Module level Other prerequisites1 semester graduate --
Contents
German contents available but not translated yet. Materialeigenschaften von Metallen und Keramiken: Korrelation von Struktur-/Eigenschaftsbeziehungen durchExperimente und Simulationen.
Intended learning outcomes
German intended learning outcomes available but not translated yet. Der/Die Studierende bekommt einen Einblick in die Eigenschaften moderner Werkstoffe: Flugzeugaluminiumle-gierungen und Hochleistungskeramiken. Es werden Messmethoden und Berechnungen durch numerische Simu-lationsverfahren vorgestellt. Besonders betont wird die Beziehung zwischen der mikro-/nanoskopischen Struk-tur der Werkstoffe und der daraus abgeleiteten Materialeigenschaften.
Courses (type, number of weekly contact hours, language — if other than German)
V + S (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
talk (approx. 45 minutes)
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 106 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationAdvanced Seminar Nanostructure Technology 11-OSN-111-m01
Module coordinator Module offered by
Managing Directors of the Institute of Applied Physics andthe Institute of Theoretical Physics and Astrophysics
Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)4 numerical grade --
Duration Module level Other prerequisites1 semester graduate --
Contents
Seminar on current issues in theoretical or experimental physics.
Intended learning outcomes
In-depth knowledge about a current topic in experimental or theoretical physics. Ability to read scientific publica-tions, summarizing them and presenting them to a peer audience.
Courses (type, number of weekly contact hours, language — if other than German)
S (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
talk with discussion (approx. 30 to 45 minutes)Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 107 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationCurrent Topics in Nanostructure Technology 11-EXN5-111-m01
Module coordinator Module offered by
chairperson of examination committee Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)5 numerical grade --
Duration Module level Other prerequisites1 semester graduate Approval by examination committee required.
Contents
Current topics in experimental physics. Credited academic achievements, e.g. in case of change of university orstudy abroad.
Intended learning outcomes
The student posseses advanced knowledge meeting the requirements of a module in Nanostructure Technolo-gy on Master's level. He/She commands knowledge in a current field in Nanostructure Technology respective Na-noscience and insight into the measuring and evaluation methods which are necessary to acquire this knowled-ge. He/She is able to classify and to link the learnt. He/She knows about fields of application.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 120 minutes, for modules with less than 4 ECTS credits approx. 90 minutes; un-less otherwise specified) or b) oral examination of one candidate each or oral examination in groups (approx. 30minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c) project report (ap-prox. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation (approx. 30 minu-tes)Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 108 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationCurrent Topics in Nanostructure Technology 11-EXN6-111-m01
Module coordinator Module offered by
chairperson of examination committee Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Approval by examination committee required.
Contents
Current topics in experimental physics. Credited academic achievements, e.g. in case of change of university orstudy abroad.
Intended learning outcomes
The student posseses advanced knowledge meeting the requirements of a module in Nanostructure Technolo-gy on Master's level. He/She commands knowledge in a current field in Nanostructure Technology respective Na-noscience and insight into the measuring and evaluation methods which are necessary to acquire this knowled-ge. He/She is able to classify and to link the learnt. He/She knows about fields of application.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 120 minutes, for modules with less than 4 ECTS credits approx. 90 minutes; un-less otherwise specified) or b) oral examination of one candidate each or oral examination in groups (approx. 30minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c) project report (ap-prox. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation (approx. 30 minu-tes)Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 109 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationCurrent Topics in Nanostructure Technology 11-EXN7-111-m01
Module coordinator Module offered by
chairperson of examination committee Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)7 numerical grade --
Duration Module level Other prerequisites1 semester graduate Approval by examination committee required.
Contents
Current topics in experimental physics. Credited academic achievements, e.g. in case of change of university orstudy abroad.
Intended learning outcomes
The student posseses advanced knowledge meeting the requirements of a module in Nanostructure Technolo-gy on Master's level. He/She commands knowledge in a current field in Nanostructure Technology respective Na-noscience and insight into the measuring and evaluation methods which are necessary to acquire this knowled-ge. He/She is able to classify and to link the learnt. He/She knows about fields of application.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 120 minutes, for modules with less than 4 ECTS credits approx. 90 minutes; un-less otherwise specified) or b) oral examination of one candidate each or oral examination in groups (approx. 30minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c) project report (ap-prox. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation (approx. 30 minu-tes)Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 110 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationCurrent Topics in Nanostructure Technology 11-EXN8-111-m01
Module coordinator Module offered by
chairperson of examination committee Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)8 numerical grade --
Duration Module level Other prerequisites1 semester graduate Approval by examination committee required.
Contents
Current topics in experimental physics. Credited academic achievements, e.g. in case of change of university orstudy abroad.
Intended learning outcomes
The student posseses advanced knowledge meeting the requirements of a module in Nanostructure Technolo-gy on Master's level. He/She commands knowledge in a current field in Nanostructure Technology respective Na-noscience and insight into the measuring and evaluation methods which are necessary to acquire this knowled-ge. He/She is able to classify and to link the learnt. He/She knows about fields of application.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 120 minutes, for modules with less than 4 ECTS credits approx. 90 minutes; un-less otherwise specified) or b) oral examination of one candidate each or oral examination in groups (approx. 30minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c) project report (ap-prox. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation (approx. 30 minu-tes)Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 111 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationCurrent Topics in Physics 11-EXP5-111-m01
Module coordinator Module offered by
chairperson of examination committee Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)5 numerical grade --
Duration Module level Other prerequisites1 semester graduate Approval by examination committee required.
Contents
Current topics in experimental or theoretical physics. Credited academic achievements, e.g. in case of change ofuniversity or study abroad.
Intended learning outcomes
The student posseses advanced knowledge meeting the requirements of a module in theoretical or experimentalphysics on Master's level in the study programme Nanostructure Technology. He/She commands knowledge ina current field in physics and insight into the measuring and calculating methods which are necessary to acquirethis knowledge. He/She is able to classify and to link the learnt. He/She knows about fields of application.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 120 minutes, for modules with less than 4 ECTS credits approx. 90 minutes; un-less otherwise specified) or b) oral examination of one candidate each or oral examination in groups (approx. 30minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c) project report (ap-prox. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation (approx. 30 minu-tes)Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 112 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationCurrent Topics in Physics 11-EXP6-111-m01
Module coordinator Module offered by
chairperson of examination committee Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Approval by examination committee required.
Contents
Current topics in experimental or theoretical physics. Credited academic achievements, e.g. in case of change ofuniversity or study abroad.
Intended learning outcomes
The student posseses advanced knowledge meeting the requirements of a module in theoretical or experimentalphysics on Master's level in the study programme Nanostructure Technology. He/She commands knowledge ina current field in physics and insight into the measuring and calculating methods which are necessary to acquirethis knowledge. He/She is able to classify and to link the learnt. He/She knows about fields of application.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 120 minutes, for modules with less than 4 ECTS credits approx. 90 minutes; un-less otherwise specified) or b) oral examination of one candidate each or oral examination in groups (approx. 30minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c) project report (ap-prox. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation (approx. 30 minu-tes)Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 113 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationCurrent Topics in Physics 11-EXP7-111-m01
Module coordinator Module offered by
chairperson of examination committee Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)7 numerical grade --
Duration Module level Other prerequisites1 semester graduate Approval by examination committee required.
Contents
Current topics in experimental or theoretical physics. Credited academic achievements, e.g. in case of change ofuniversity or study abroad.
Intended learning outcomes
The student posseses advanced knowledge meeting the requirements of a module in theoretical or experimentalphysics on Master's level in the study programme Nanostructure Technology. He/She commands knowledge ina current field in physics and insight into the measuring and calculating methods which are necessary to acquirethis knowledge. He/She is able to classify and to link the learnt. He/She knows about fields of application.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 120 minutes, for modules with less than 4 ECTS credits approx. 90 minutes; un-less otherwise specified) or b) oral examination of one candidate each or oral examination in groups (approx. 30minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c) project report (ap-prox. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation (approx. 30 minu-tes)Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationCurrent Topics in Physics 11-EXP8-111-m01
Module coordinator Module offered by
chairperson of examination committee Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)8 numerical grade --
Duration Module level Other prerequisites1 semester graduate Approval by examination committee required.
Contents
Current topics in experimental or theoretical physics. Credited academic achievements, e.g. in case of change ofuniversity or study abroad.
Intended learning outcomes
The student posseses advanced knowledge meeting the requirements of a module in theoretical or experimentalphysics on Master's level in the study programme Nanostructure Technology. He/She commands knowledge ina current field in physics and insight into the measuring and calculating methods which are necessary to acquirethis knowledge. He/She is able to classify and to link the learnt. He/She knows about fields of application.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 120 minutes, for modules with less than 4 ECTS credits approx. 90 minutes; un-less otherwise specified) or b) oral examination of one candidate each or oral examination in groups (approx. 30minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c) project report (ap-prox. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation (approx. 30 minu-tes)Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationBasic Course German Civil Code 1 02-N-P-G1-101-m01
Module coordinator Module offered by
Dean of Studies Faculty of Law Faculty of Law
ECTS Method of grading Only after succ. compl. of module(s)10 numerical grade --
Duration Module level Other prerequisites1 semester undergraduate Admission prerequisite to assessment: regular attendance of conversato-
rium.
Contents
German contents available but not translated yet. Der Grundkurs Bürgerliches Recht 1 führt die Studierenden in das Privatrecht ein. Er bietet eine systematischeDarstellung des Allgemeinen Teils des Bürgerlichen Gesetzbuches sowie wichtiger Fragen des Schuldrechts, All-gemeiner Teil.
Intended learning outcomes
German intended learning outcomes available but not translated yet. Die Studierenden haben umfassende Kenntnisse auf dem Gebiet des Allgemeinen Teils des Bürgerlichen Gesetz-buchs erworben. Neben der Auseinandersetzung mit Problemen des Allgemeinen Teils, lernten sie die Systema-tik des BGB kennen und erlernten das Arbeiten mit juristischen Fällen anhand von Beispielen.
Courses (type, number of weekly contact hours, language — if other than German)
V + 0 (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 120 minutes) or b) oral examination (approx. 15 minutes)
Allocation of places
Degree programm law (degree "Erste Juristische Staatsprüfung") and Bachelor's Privatrecht (Private Law) (minorwith 60 ECTS credits): no restrictions. Students of other degree programmes: 20 places. Places will be allocatedas follows: Students applying after not having successfully completed assessment in in the last two semesterswill be given preferential consideration. The remaining places will be allocated by lot. A waiting list will be main-tained and places re-allocated as they become available.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationBasic Course German Civil Code 2a and 2 b 02-N-P-G2-101-m01
Module coordinator Module offered by
Dean of Studies Faculty of Law Faculty of Law
ECTS Method of grading Only after succ. compl. of module(s)10 numerical grade --
Duration Module level Other prerequisites1 semester undergraduate --
Contents
German contents available but not translated yet. Der Grundkurs Bürgerliches Recht 2.1 erschließt den für das Bürgerliche Recht zentralen Bereich des Allgemei-nen Schuldrechts einschließlich der Leistungsstörungen sowie die wichtigsten Fragen der vertraglichen Schuld-verhältnisse. Die Vorlesung Grundkurs Bürgerliches Recht 2.2 behandelt die gesetzlichen Schuldverhältnisse Ge-schäftsführung ohne Auftrag, Bereicherungsrecht und Deliktsrecht.
Intended learning outcomes
German intended learning outcomes available but not translated yet. Die Studierenden verfügen über grundlegendes Wissen auf dem Gebiet des Schuldrechts des Bürgerlichen Ge-setzbuchs (§§241-432 BGB). Sie haben insbesondere Kenntnisse auf dem Gebiet des Leistungsstörungsrechtserworben und sich mit den bedeutendsten vertraglichen Schuldverhältnissen wie dem Kaufvertrag, Werkvertrag,Darlehensvertrag und der Bürgschaft sowie den gesetzlichen Schuldverhältnissen auseinandergesetzt. Die Stu-dierenden erlernten anhand von ausgewählten Problemen des Schuldrechts das juristische Arbeiten.
Courses (type, number of weekly contact hours, language — if other than German)
V + V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
written examination (approx. 120 minutes)
Allocation of places
Degree programm law (degree "Erste Juristische Staatsprüfung") and Bachelor's Privatrecht (Private Law) (minorwith 60 ECTS credits): no restrictions. Students of other degree programmes: 20 places. Places will be allocatedas follows: Students applying after not having successfully completed assessment in in the last two semesterswill be given preferential consideration. The remaining places will be allocated by lot. A waiting list will be main-tained and places re-allocated as they become available.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationBasic Course German Civil Code 3 02-N-P-G3-101-m01
Module coordinator Module offered by
Dean of Studies Faculty of Law Faculty of Law
ECTS Method of grading Only after succ. compl. of module(s)10 numerical grade --
Duration Module level Other prerequisites1 semester undergraduate Admission prerequisite to assessment: regular attendance of conversato-
rium.
Contents
German contents available but not translated yet. Gegenstand des Moduls ist das dritte Buch des BGB. Es werden die Grundlagen auf dem Gebiet des Sachen-rechts vermittelt.
Intended learning outcomes
German intended learning outcomes available but not translated yet. Die Studierenden haben grundlegendes Wissen auf dem Gebiet des Sachenrechts erworben. Sie haben insbe-sondere Kenntnisse über Rechtsfragen zu Besitz und Besitzschutz, das Eigentum und Fragen des Nachbarrechts,das allgemeine Grundstücksrecht, den Eigentumserwerb an Grundstücken und an beweglichen Sachen, dasRechtsverhältnis zwischen Eigentümer und Besitzer und beschränkt dingliche Rechte, wie die Dienstbarkeitenund die Sicherungsrechte (Hypothek, Grundschuld, Pfandrecht).
Courses (type, number of weekly contact hours, language — if other than German)
V + 0 (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 120 minutes) or b) oral examination (approx. 15 minutes)
Allocation of places
Degree programm law (degree "Erste Juristische Staatsprüfung") and Bachelor's Privatrecht (Private Law) (minorwith 60 ECTS credits): no restrictions. Students of other degree programmes: 20 places. Places will be allocatedas follows: Students applying after not having successfully completed assessment in in the last two semesterswill be given preferential consideration. The remaining places will be allocated by lot. A waiting list will be main-tained and places re-allocated as they become available.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationGerman and European Trade Mark Law 02-N-P-W06-111-m01
Module coordinator Module offered by
Dean of Studies Faculty of Law Faculty of Law
ECTS Method of grading Only after succ. compl. of module(s)3 numerical grade --
Duration Module level Other prerequisites1 semester undergraduate --
Contents
German contents available but not translated yet. Die Vorlesung vermittelt einen Überblick über das Deutsche und Europäische Markenrecht. Neben den Grundla-gen des Markenbegriffs und -schutzes nach dem deutschen Markengesetz werden u.a. die Voraussetzungen undWirkungen der Europäischen Gemeinschaftsmarke nach der Gemeinschaftsmarkenverordnung behandelt. Fernerwerden Spezialregelungen des deutschen Markenrechts wie z.B. zu geschäftlichen Bezeichnungen, geographi-schen Herkunftsangaben sowie zum kennzeichenrechtlichen Schutz von Internet Domains besprochen.
Intended learning outcomes
German intended learning outcomes available but not translated yet. Die Studierenden können markenrechtliche Fragestellungen unter Gesichtspunkten des deutschen und europäi-schen Rechts analysieren.
Courses (type, number of weekly contact hours, language — if other than German)
V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 120 minutes) or b) oral examination (approx. 15 minutes)Assessment offered: usually once a year, summer semester
Allocation of places
Degree programm law (degree "Erste Juristische Staatsprüfung") and Bachelor's Privatrecht (Private Law) (minorwith 60 ECTS credits): no restrictions. Students of other degree programmes: 20 places. Places will be allocatedas follows: Students applying after not having successfully completed assessment in in the last two semesterswill be given preferential consideration. The remaining places will be allocated by lot. A waiting list will be main-tained and places re-allocated as they become available.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationCopyright Law and Fundamentals of Patent Law including references to EU Law 02-N-P-W07-111-m01
Module coordinator Module offered by
Dean of Studies Faculty of Law Faculty of Law
ECTS Method of grading Only after succ. compl. of module(s)2 numerical grade --
Duration Module level Other prerequisites1 semester undergraduate --
Contents
German contents available but not translated yet. Die Veranstaltung behandelt neben den allgemeinen Grundlagen des Gewerblichen Rechtsschutzes den Schutzvon Werken nach dem deutschen Urhebergesetz. In einem weiteren Veranstaltungsteil werden das Geschmacks-musterrecht sowie das Patent- und Gebrauchsmusterrecht beleuchtet.
Intended learning outcomes
German intended learning outcomes available but not translated yet. Die Studierenden haben grundlegende Kenntnisse des Gewerblichen Rechtsschutzes und des Urheberrechts er-worben. Sie können Problematiken aus diesen Bereichen in den Kontext der deutschen und europäischen Rege-lungen einordnen.
Courses (type, number of weekly contact hours, language — if other than German)
V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 120 minutes) or b) oral examination (approx. 15 minutes)Assessment offered: usually once a year, summer semester
Allocation of places
Degree programm law (degree "Erste Juristische Staatsprüfung") and Bachelor's Privatrecht (Private Law) (minorwith 60 ECTS credits): no restrictions. Students of other degree programmes: 20 places. Places will be allocatedas follows: Students applying after not having successfully completed assessment in in the last two semesterswill be given preferential consideration. The remaining places will be allocated by lot. A waiting list will be main-tained and places re-allocated as they become available.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationAdditional Qualifications for Engineers 11-EXZ5-111-m01
Module coordinator Module offered by
chairperson of examination committee Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)5 numerical grade --
Duration Module level Other prerequisites1 semester graduate Approval by examination committee required.
Contents
Additional qualifications for engineers. Credited academic achievements, e.g. in case of change of university orstudy abroad.
Intended learning outcomes
The student posseses advanced knowledge meeting the requirements of a module on Master's level in the stu-dy program Nanostructure Technology. He/She commands knowledge qualifying him/her for a job in industry re-spective industrial research and development.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 120 minutes, for modules with less than 4 ECTS credits approx. 90 minutes; un-less otherwise specified) or b) oral examination of one candidate each or oral examination in groups (approx. 30minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c) project report (ap-prox. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation (approx. 30 minu-tes)Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationAdditional Qualifications for Engineers 11-EXZ6-111-m01
Module coordinator Module offered by
chairperson of examination committee Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Approval by examination committee required.
Contents
Additional qualifications for engineers. Credited academic achievements, e.g. in case of change of university orstudy abroad.
Intended learning outcomes
The student posseses advanced knowledge meeting the requirements of a module on Master's level in the stu-dy program Nanostructure Technology. He/She commands knowledge qualifying him/her for a job in industry re-spective industrial research and development.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 120 minutes, for modules with less than 4 ECTS credits approx. 90 minutes; un-less otherwise specified) or b) oral examination of one candidate each or oral examination in groups (approx. 30minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c) project report (ap-prox. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation (approx. 30 minu-tes)Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationMaster Thesis Nanostructure Technology 11-MA-N-111-m01
Module coordinator Module offered by
chairperson of examination committee Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)30 numerical grade --
Duration Module level Other prerequisites1 semester graduate --
Contents
Independent work on an experimental, theoretical or ingeneering research task within nanotechnology research,in particular using state-of-the-art methods and according to scientific aspects. Writing of the master thesis.
Intended learning outcomes
Ability to independently work on an experimental, theoretical or engineering task in nanotechnology research, inparticular according to state-of-the-art methods and scientific aspects, and to discuss and present it in a writtenfinal thesis.
Courses (type, number of weekly contact hours, language — if other than German)
no courses assigned
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
written thesisLanguage of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationEmployment law for non-law students 02-J7-112-m01
Module coordinator Module offered by
holder of the Chair of Civil Law, Employment and LabourLaw and Civil Procedure
Faculty of Law
ECTS Method of grading Only after succ. compl. of module(s)3 numerical grade --
Duration Module level Other prerequisites1 semester undergraduate --
Contents
German contents available but not translated yet. Die Veranstaltung Arbeitsrecht für Studierende anderer Fachrichtungen vermittelt die Grundlagen des Arbeits-rechts.
Intended learning outcomes
German intended learning outcomes available but not translated yet. Die Studierenden haben gelernt, arbeitsrechtliche Grundlagen auf ein späteres berufliches Handlungsfeld zu ap-plizieren.
Courses (type, number of weekly contact hours, language — if other than German)
V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
written examination (approx. 120 minutes)Assessment offered: once a year, winter semester
Allocation of places
Number of places: maximum 50. Students applying after not having successfully completed assessment in thepast two semesters will be given preferential consideration. The remaining places will be allocated by lot. A wai-ting list will be maintained and places re-allocated by lot as they become available. Places on all courses of themodule component with a restricted number of places will be allocated in the same procedure.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationPrinciples of two- and threedimensional Röntgen imaging 11-ZDR-111-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
German contents available but not translated yet. Physik der Röntgenstrahlerzeugung (Röntgenröhren, Synchrotron). Physik der Wechselwirkung von Röntgen-strahlung und Materie (Phototabsorption, Streuung) , Physik der Röntgenstrahldetektion. Mathematik der Rekon-struktionsalgorithmen (Gefilterte Rückprojektion, Fourierrekonstruktion, Iterative Methoden). Bildverarbeitung(Bilddatenvorverarbeitung, Merkmalsextraktion, Visualisierung, ... ). Anwendungen der Röntgenbildgebung inder Industrie (Bauteilprüfung, Materialcharakterisierung, Metrologie, Biologie, ...). Strahlenschutz und biologi-sche Strahlenwirkung (Dosis, ...)
Intended learning outcomes
German intended learning outcomes available but not translated yet. Die Studierenden kennen die Grundlagen der Erzeugung von Röntgenstrahlung und ihrer Wechselwirkung mitMaterie. Sie kennen bildgebende Verfahren unter Verwendung von Röntgenstrahlung und Methoden zur Bildver-arbeitung sowie die Anwendungsgebiete dieser Methoden.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationIntroduction to Electron Microscopy 11-IEM-111-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)4 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
1. Microscopy with light and electrons. 2. Electrons and their interaction with a specimen. 3. Electron diffraction(selected-area ED, convergent beam ED, basics of electron crystallography, comparison with the X-ray diffracti-on technique). 4. Transmission electron microscopy (the instrument, contrast mechanisms, principles of imageformation, imaging of microstructure). 5. Can we see atoms? High-resolution electron microscopy (principle ofimage formation, image simulation). 6. Scanning electron microscopy (the instrument, contrast mechanisms).7. Chemical analysis with the electron microscope (energy-dispersive X-ray microanalysis, electron energy lossspectroscopy). 8. Sample preparation. Electron microscopy and complementary techniques.
Intended learning outcomes
German intended learning outcomes available but not translated yet. Die Studierenden verfügen über wesentliche Kenntnisse über moderne Untersuchungsmethoden der Elektro-nemmikroskopie bis hinunter zur atomaren Skala. Sie kennen Mikroskopieverfahren, die in der Labor- und Indu-striepraxis verwendet werden und elektronenmikroskopische Methoden zur chemischen Analyse. Sie sind in derLage, die Leistungsfähigkeit verschiedener Untersuchungsmethoden zu beurteilen.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationField Theory in Solid State Physics 11-FTFK-112-m01
Module coordinator Module offered by
Managing Director of the Institute of Theoretical Physicsand Astrophysics
Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)8 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
This will usually be a course on quantum many particle physics using the method of functional integration. Anoutline could be:1 Coherent states and review of second quantization2 The functional integral formalism at finite temperatures T3 Perturbation theory at T=04 Order parameters and broken symmetry5 Green's functions6 The Landau theory of Fermi liquids7 Further developments
Intended learning outcomes
Working knowledge of quantum many particle physics on the basis of the modern method of path integrals andfunctional integration, complementing the traditional approach using Green's functions and Feynman diagrams.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c)project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationVisiting Research Project 11-FPA-112-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)10 numerical grade --
Duration Module level Other prerequisites1 semester graduate Approval by examination committee required.
Contents
Independent work in a current research topic in experimental or theoretical physics. Experimental work includinganalysis and documentation of the results, especially in the context of research visits to other universities or re-search institutes.
Intended learning outcomes
Familiarity with current research topics in experimental or theoretical physics. Within experimental physics, theability to analyze and document scientific experiments.
Courses (type, number of weekly contact hours, language — if other than German)
R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
project report (approx. 10 to 20 pages)Language of assessment: German, English
Allocation of places
--
Additional information
Additional information on module duration: 1 to 2 semesters.
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationEuropean Company Law 02-N-P-W04-112-m01
Module coordinator Module offered by
Dean of Studies Faculty of Law Faculty of Law
ECTS Method of grading Only after succ. compl. of module(s)2 numerical grade --
Duration Module level Other prerequisites1 semester undergraduate --
Contents
German contents available but not translated yet. Die Vorlesung behandelt die Einflüsse des Gemeinschaftsrechts auf das Gesellschaftsrecht: Niederlassungsfrei-heit des EG-Vertrages, Rechtsangleichung durch Richtlinien, supranationale Rechtsformen.
Intended learning outcomes
German intended learning outcomes available but not translated yet. Die Studierenden haben die in den letzten Jahren immer stärker in den Vordergrund getretenen europäischen Be-züge des Gesellschaftsrechts erlernt und können das deutsche Gesellschaftsrecht in den Kontext seiner europäi-schen Entwicklung einordnen.
Courses (type, number of weekly contact hours, language — if other than German)
V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 120 minutes) or b) oral examination (approx. 15 minutes)Assessment offered: once a year, winter semester
Allocation of places
Students of the degree programme Rechtswissenschaften (Law) with the degree Erste Juristische Staatsprüfung(first state examination in law) and students of the Bachelor's degree programme Privatrecht (Private Law) (mi-nor with 60 ECTS credits): no restrictions. Students of other degree programmes: 20 places, 10 of which will beset aside for Master's students of Economics. Should the number of places available exceed the number of app-lications, the remaining places can be allocated to students of other subjects/degree programmes. Should the-re be more than 10 applications from students of other subjects, the remaining 10 places will be allocated as fol-lows: Students applying after not having successfully completed assessment in past years will be given preferen-tial consideration. The remaining places will be allocated by lot. A waiting list will be maintained and places re-allocated as they become available.
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationNon-technical Minor Subject 11-EXNT6-112-m01
Module coordinator Module offered by
chairperson of examination committee Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Approval by examination committee required.
Contents
Non-technical minor. Crediting for academic achievements, e.g. from university change or study abroad
Intended learning outcomes
The student posseses advanced knowledge on Master's level meeting the requirements of a module in the fieldof a non physical minor subject (mathematics, chemistry, computer science, legal science, economics,...).
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 120 minutes) or b) oral examination of one candidate each or oral examinationin groups (approx. 30 minutes per candidate) or c) project report (approx. 8 to 10 pages, time to complete: 1 to 4weeks) or d) presentation/seminar presentation (approx. 30 minutes)Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationCurrent Topics in Nanostructure Technology 11-EXN6A-112-m01
Module coordinator Module offered by
chairperson of examination committee Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Approval by examination committee required.
Contents
Current topics in experimental physics. Credited academic achievements, e.g. in case of change of university orstudy abroad.
Intended learning outcomes
The student posseses advanced knowledge meeting the requirements of a module in Nanostructure Technolo-gy on Master's level. He/She commands knowledge in a current field in Nanostructure Technology respective Na-noscience and insight into the measuring and evaluation methods which are necessary to acquire this knowled-ge. He/She is able to classify and to link the learnt. He/She knows about fields of application.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 120 minutes) or b) oral examination of one candidate each or oral examinationin groups (approx. 30 minutes per candidate) or c) project report (approx. 8 to 10 pages, time to complete: 1 to 4weeks) or d) presentation/seminar presentation (approx. 30 minutes)Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationCurrent Topics of Physics 11-EXP6A-112-m01
Module coordinator Module offered by
chairperson of examination committee Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Approval by examination committee required.
Contents
Current topics in experimental or theoretical physics. Credited academic achievements, e.g. in case of change ofuniversity or study abroad.
Intended learning outcomes
The student posseses advanced knowledge meeting the requirements of a module in theoretical or experimentalphysics on Master's level in the study programme Nanostructure Technology. He/She commands knowledge ina current field in physics and insight into the measuring and calculating methods which are necessary to acquirethis knowledge. He/She is able to classify and to link the learnt. He/She knows about fields of application.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 120 minutes, for modules with less than 4 ECTS credits approx. 90 minutes; un-less otherwise specified) or b) oral examination of one candidate each or oral examination in groups (approx. 30minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c) project report (ap-prox. 8 to 10 pages, time to complete: 1 to 4 weeks) or d) presentation/seminar presentation (approx. 30 minu-tes)Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationMethods for non-destructive Characterization of Materials and Components 11-ZMB-112-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)4 numerical grade --
Duration Module level Other prerequisites1 semester undergraduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
German contents available but not translated yet. Methoden zur zerstörungsfreien Material- und Bauteilcharakterisierung
Intended learning outcomes
German intended learning outcomes available but not translated yet. Die Studierenden kennen Methoden zur zerstörungsfreien Charakterisierung von Materialien und Bauteilen.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examination ingroups (approx. 30 minutes per candidate) or c) project report (approx. 10 pages, time to complete: 1 to 4 weeks)or d) presentation/seminar presentation (approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationImage and Signal Processing in Physics 11-BSV-122-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
Periodic and aperiodic signals; basic principles of the discrete and exact Fourier transformation; basic principlesof the digital signal and image processing; discretization of signals/Shannon sampling theorem; Parsival theo-rem, correlation and energy consideration; statistical signals, image noise, moments, stationary signals; tomo-graphy: Hankel and Radon transformation.
Intended learning outcomes
Advanced knowledge about digital image and signal processing. Familiarity with the physical principles of imageprocessing and various methods of signal processing. Capability of describing the various methods and in parti-cular of applying them to tomography.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (90 minutes) or b) oral examination of one candidate each or oral examination in groups(approx. 30 minutes per candidate) or c) project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) ord) presentation/seminar presentation (approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationImaging Methods at the Synchrotron 11-BMS-121-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)4 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
German contents available but not translated yet. - Übersicht über Synchroton Strahlung und deren Erzeugung. - Grundlagen der Wechselwirkung Strahlung-Mate-rie. - Grundlagen der Röntgenoptik, Röntgenlinsen. - Detektortechnik am Synchroton. - Röntgendiffraktoktometrie(beugung) an kristallinen Materialien.
Intended learning outcomes
German intended learning outcomes available but not translated yet. Der/Die Studierende verfügt über fortgeschrittene Kenntnisse der Synchrotronstrahlung und Röntgenoptik. Er/Sie kennt die physikalischen Grundlagen bildgebender Verfahren am Synchrotron und deren Anwendung u.a. ankristallinen Materialien. Er/Sie versteht die Prinzipien der Bildentstehung und ist in der Lage, die verschiedenenVerfahren zu erläutern und einfache Bilder zu interpretieren.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (90 minutes) or b) oral examination of one candidate each or oral examination in groups(approx. 30 minutes per candidate) or c) project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) ord) presentation/seminar presentation (approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationComputational Materials Science 11-CMS-122-m01
Module coordinator Module offered by
Managing Director of the Institute of Theoretical Physicsand Astrophysics
Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)8 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semester. For as-sessment at a later date, students will have to obtain the qualification foradmission to assessment anew.
Contents
1. Density functional theory (DFT)2. Wannier functions and localized basis functions3. Numerical evaluation of topological invariants4. Hartree-Fock and static mean-field theory5. Many-body methods for solid state physics6. Anderson impurity model (AIM) and Kondo physics7. Dynamical mean-field theory (DMFT)8. DFT + DMFT methods for realistic modeling of solids9. Strongly correlated electrons
Intended learning outcomes
Theoretical treatment of the above topics complemented by hands-on tutorials to be held in the CIP-Pool. Fami-liarity with DFT software packages such as VASP or Wien2k and and construction of maximally localized Wannierfunctions by projecting DFT results onto atomic orbitals using wannier90. Focus on applications to topologicalmaterials. Knowledge how to obtain many-body solutions of the AIM and explore some of its limiting cases suchas the Kondo regime. Ability to use impurity solvers based on exact diagonalization or continuous-time quantumMonte Carlo for the solution of the DMFT self-consistency equations.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (90 minutes) or b) oral examination of one candidate each or oral examination in groups(approx. 30 minutes per candidate) or c) project report (approx. 8 to 10 pages, time to complete: 1 to 4 weeks) ord) presentation/seminar presentation (approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German or English
Allocation of places
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 137 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationComputational Materials Science 11-CMS-131-m01
Module coordinator Module offered by
Managing Director of the Institute of Theoretical Physicsand Astrophysics
Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)8 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semesters.
Contents
1. Density functional theory (DFT)2. Wannier functions and localized basis functions3. Numerical evaluation of topological invariants4. Hartree-Fock and static mean-field theory5. Many-body methods for solid state physics6. Anderson impurity model (AIM) and Kondo physics7. Dynamical mean-field theory (DMFT)8. DFT + DMFT methods for realistic modeling of solids9. Strongly correlated electrons
Intended learning outcomes
Theoretical treatment of the above topics complemented by hands-on tutorials to be held in the CIP-Pool. Fami-liarity with DFT software packages such as VASP or Wien2k and and construction of maximally localized Wannierfunctions by projecting DFT results onto atomic orbitals using wannier90. Focus on applications to topologicalmaterials. Knowledge how to obtain many-body solutions of the AIM and explore some of its limiting cases suchas the Kondo regime. Ability to use impurity solvers based on exact diagonalization or continuous-time quantumMonte Carlo for the solution of the DMFT self-consistency equations.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examinationin groups (approx. 30 minutes per candidate) or c) project report (approx. 8 to 10 pages, time to complete: 1 to 4weeks) or d) presentation/seminar presentation (approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationImaging Methods at the Synchrotron 11-BMS-131-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)4 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semesters.
Contents
German contents available but not translated yet. - Übersicht über Synchroton Strahlung und deren Erzeugung. - Grundlagen der Wechselwirkung Strahlung-Mate-rie. - Grundlagen der Röntgenoptik, Röntgenlinsen. - Detektortechnik am Synchroton. - Röntgendiffraktoktometrie(beugung) an kristallinen Materialien.
Intended learning outcomes
German intended learning outcomes available but not translated yet. Der/Die Studierende verfügt über fortgeschrittene Kenntnisse der Synchrotronstrahlung und Röntgenoptik. Er/Sie kennt die physikalischen Grundlagen bildgebender Verfahren am Synchrotron und deren Anwendung u.a. ankristallinen Materialien. Er/Sie versteht die Prinzipien der Bildentstehung und ist in der Lage, die verschiedenenVerfahren zu erläutern und einfache Bilder zu interpretieren.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examinationin groups (approx. 30 minutes per candidate) or c) project report (approx. 8 to 10 pages, time to complete: 1 to 4weeks) or d) presentation/seminar presentation (approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationImage and Signal Processing in Physics 11-BSV-131-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semesters.
Contents
Periodic and aperiodic signals; basic principles of the discrete and exact Fourier transformation; basic principlesof the digital signal and image processing; discretization of signals/Shannon sampling theorem; Parsival theo-rem, correlation and energy consideration; statistical signals, image noise, moments, stationary signals; tomo-graphy: Hankel and Radon transformation.
Intended learning outcomes
Advanced knowledge about digital image and signal processing. Familiarity with the physical principles of imageprocessing and various methods of signal processing. Capability of describing the various methods and in parti-cular of applying them to tomography.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examinationin groups (approx. 30 minutes per candidate) or c) project report (approx. 8 to 10 pages, time to complete: 1 to 4weeks) or d) presentation/seminar presentation (approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
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Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationApplied Superconduction 11-ASL-131-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate Certain prerequisites must be met to qualify for admission to as-
sessment. The lecturer will inform students about the respective detailsat the beginning of the course. Registration for the course will be con-sidered a declaration of will to seek admission to assessment. If stu-dents have obtained the qualification for admission to assessment overthe course of the semester, the lecturer will put their registration for as-sessment into effect. Students who meet all prerequisites will be admit-ted to assessment in the current or in the subsequent semesters.
Contents
German contents available but not translated yet. Physikalische Grundlagen der Supraleitung. Anwendungen in der Energietechnik. Apparative Entwicklungen. Me-thoden der Materialwissenschaften zur Berechnung von Temperaturprofilen in Supraleitern
Intended learning outcomes
German intended learning outcomes available but not translated yet. Die Studierenden verfügen über ein Grundverständnis der Supraleitung als ein makroskopisch beobachtbaresQuantenphänomen. Sie sind in der Lage, in Grundzügen die Beiträge der Materialwissenschaften zur Weiterent-wicklung der Supraleitung zu beurteilen. Sie haben die Fähigkeit, Fragen zur Supraleitung wissenschaftlich zudiskutieren und energietechnische Entwicklungen kritisch zu hinterfragen. Sie sind ferner in der Lage, praktischeFragestellungen mathematisch zu behandeln.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examinationin groups (approx. 30 minutes per candidate) or c) project report (approx. 8 to 10 pages, time to complete: 1 to 4weeks) or d) presentation/seminar presentation (approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
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Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 143 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationSolid State Spectroscopy 2 11-FKS2-132-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate --
Contents
Modern scattering methods; neutron scattering as a method to investigate the atomic and magnetic structure, aswell as excitations such as phonons and magnetic waves; resonant elastic x-ray scattering and absorption; inve-stigation of magnetic, orbital and charge order; x-ray and neutron reflectometry; investigation of the structural,magnetic and electronic properties of thin films and superlattices; resonant inelastic x-ray scattering; investiga-tion of excitations in solids and thin films; STEM ("Scanning transmission electron microscopy"); further topicsupon agreement.
Intended learning outcomes
Knowledge of various modern scattering techniques such as neutron scattering, resonant elastic x-ray scatte-ring, modern scattering theory, x-ray and neutron reflectometry, and resonant inelastic x-ray scattering. Familiari-ty with the theoretical principles and with applications of these methods
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examinationin groups (approx. 30 minutes per candidate) or c) project report (approx. 8 to 10 pages, time to complete: 1 to 4weeks) or d) presentation/seminar presentation (approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 144 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationPhysics of Advanced Materials 11-PMM-132-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate --
Contents
General properties of various material groups such as liquids, liquid crystals and polymers; magnetic materi-als and superconductors; thin films, heterostructures and superlattices. Methods to characterize these materialgroups. Two-dimensional layered structures.
Intended learning outcomes
Familiarity with the properties and characterization methods of various groups of modern materials.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examinationin groups (approx. 30 minutes per candidate) or c) project report (approx. 8 to 10 pages, time to complete: 1 to 4weeks) or d) presentation/seminar presentation (approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 145 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationTopology in Solid State Physics 11-TFP-132-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate --
Contents
1. Geometric phase in quantum systems2. Mathematical basics of topology3. Time-reversal symmetry4. Hall conductance and Chern numbers5. Bulk-boundary correspondence6. Graphene (as a topological insulator)7. Quantum Spin Hall insulators8. Z2 invariants9. Topological superconductors
Intended learning outcomes
In-depth theoretical understanding of the topological concepts in quantum physics related to solid state sy-stems. Ability to connect their knowledge with different research activities at the Department of Physics andAstronomy at Würzburg University.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examinationin groups (approx. 30 minutes per candidate) or c) project report (approx. 8 to 10 pages, time to complete: 1 to 4weeks) or d) presentation/seminar presentation (approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 146 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationQuantum Information Technology 11-QUI-132-m01
Module coordinator Module offered by
Managing Director of the Institute of Applied Physics Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)6 numerical grade --
Duration Module level Other prerequisites1 semester graduate --
Contents
Basic concepts of quantum mechanics, quantum bits and algorithms, quantum measurements, experimental ap-proaches towards quantum computing (based on photons, ions, nuclear spins), quantum operations and noise,quantum information and communication.
Intended learning outcomes
Knowledge of fundamental concepts in quantum information technology and quantum computing. Knowledge ofexperimental strategies to realize quantum computers and quantum communication.
Courses (type, number of weekly contact hours, language — if other than German)
V + R (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examinationin groups (approx. 30 minutes per candidate) or c) project report (approx. 8 to 10 pages, time to complete: 1 to 4weeks) or d) presentation/seminar presentation (approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 Subsection 3 ASPO (general academic andexamination regulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 147 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationThermodynamics and Economics 11-TDOE-141-m01
Module coordinator Module offered by
Managing Director of the Institute of Theoretical Physicsand Astrophysics
Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)3 (not) successfully completed --
Duration Module level Other prerequisites1 semester graduate --
Contents
Energy and economic growth, entropy production and emission reduction.Part I describes the role of energy conversion in the development of the universe, the evolution of life and the un-folding of civilization. In nonequilibrium thermodynamics, the entropy production density signifies the importan-ce of the second law of thermodynamics for ecological damage and resource consumption. Energy conversion,entropy production and natural resources define the technological and ecological boundaries of industrial eco-nomic growth.Part 2 analyses how the factors capital, work, energy and creativity produce the goods and services of a nationaleconomy and determine the economic growth. In doing so it turns out that the productive power of cheap ener-gy by far exceeds that of expensive labor. Within the current system of taxes and social security contributionsthis discrepancy between power and cost of production factors leads to job cuts, waste of resources, impoveris-hment of the nation states and growing social tensions. It is discussed how Factor income taxes can counteractthis development.Part 3 treats, also in the form of seminar presentations, the techniques of rational use of energy and of the use ofnon-fossile energy sources, and introduces into the optimization program deeco (Dynamic Energy, Emission andCost Optimization).
Intended learning outcomes
In-depth understanding of how energy conversion and entropy production will co-determine the future economicand social development of the world. Comprehension of the relations between thermodynamics and economyand the description of the productive physical basis of modern economical systems as extension of economictheory. The ability to apply the learned knowledge to particular problems. NOTE: this is the module that was run by Prof. Dr. R. Kümmel, tailored on his own theory of economy. Meanwhilehe is retired. So the question would be whether we continue to offer this module or to remove it entirely.
Courses (type, number of weekly contact hours, language — if other than German)
V (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (approx. 90 minutes) or b) oral examination of one candidate each or oral examinationin groups (approx. 30 minutes per candidate) or c) project report (approx. 8 to 10 pages, time to complete: 1 to 4weeks) or d) presentation/seminar presentation (approx. 30 minutes)
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 148 / 149
Module Catalogue for the SubjectNanostructure Technology
Master’s with 1 major, 120 ECTS credits
Module title AbbreviationDensitiy Functional Theory and the Physics of Oxide Heterostructure 11-DFT-142-m01
Module coordinator Module offered by
chairperson of examination committee Faculty of Physics and Astronomy
ECTS Method of grading Only after succ. compl. of module(s)4 numerical grade --
Duration Module level Other prerequisites1 semester graduate --
Contents
Concepts and principles of Density Functional Theory. Basic use of main code packages, such as Wien2k and/orVASP. Physics of oxide Heterostructures and complex interfaces. Calculations of simple cases with DFT.
Intended learning outcomes
German intended learning outcomes available but not translated yet. Die Studierenden sind mit den physikalischen Grundlagen von Oxidheterostrukturen sowie den Grundlagen undMethoden der Dichtefunktionaltheorie vertraut. Sie sind in der Lage, Probleme der Theoretischen Physik mit Hilfevon wichtigen Programmpaketen wie Wien2k oder VASP zu modellieren. Sie können einfache Berechnungen mitHilfe der Dichtefunktionaltheorie durchführen.
Courses (type, number of weekly contact hours, language — if other than German)
V + D (no information on SWS (weekly contact hours) and course language available)
Method of assessment (type, scope, language — if other than German, examination offered — if not every seme-ster, information on whether module can be chosen to earn a bonus)
a) written examination (90 minutes) or b) oral examination of one candidate each or oral examination in groups(approx. 30 minutes per candidate, for modules with less than 4 ECTS credits approx. 20 minutes) or c) projectreport (approx. 8 to 10 pages, time to complete: approx. 1 to 4 weeks) or d) presentation/seminar presentation(approx. 30 minutes)Assessment offered: When and how often assessment will be offered depends on the method of assessmentand will be announced in due form under observance of Section 32 ASPO (general academic and examination re-gulations) 2009.Language of assessment: German, English
Allocation of places
--
Additional information
--
Referred to in LPO I (examination regulations for teaching-degree programmes)
--
Master’s with 1 major Nanostructure Technology(2011)
JMU Würzburg • generated 14-Nov-2018 • exam. reg. data record 88|224|-|-|H|2011 page 149 / 149