Upload
others
View
0
Download
0
Embed Size (px)
Citation preview
The 9th International Symposium on
Ultrafast Phenomena and Terahertz Waves
Conference Book
National University of Defense Technology
(23-26 April,2018 Changsha, China)
技科 大防 学
国
Website and Wechat public account:
Honorary Chair:
Zejin Liu, National University of
Defense Technology, China
General Chair:
Zengxiu Zhao, National University
of Defense Technology, China
Co-chairs:
Xi-Cheng Zhang, University of
Rochester, USA
Qihuang Gong, Peking University,
China
LOCAL ORGANIZING COMMITTEE:
Chair:Zengxiu Zhao
Members:Jiayu DaiDongwen ZhangZhihui LyuXiaowei WangJing ZhaoXiao ChengXiaojun WuXiaoyu PengBeibei HeLihui Xie
We gratefully acknowledge the considerable t ime and effort invested by many individuals and organizations in planning for, and running this conference.
CONTENTS:
Welcome to ISUPTW2018∙∙∙∙∙∙∙∙∙∙∙∙1
Committees∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙5
General Information∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙7
Daily Schedule∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙11
Plenary Presentations∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙13
Full Technical Program∙∙∙∙∙∙∙∙∙∙∙∙∙∙22
Author Index∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙67
Sponsors∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙∙76
1
WELCOME TO ISUPTW 2018
Welcome to the 9th International Symposium on Ultrafast Phenomena and
Terahertz Waves (ISUPTW 2018). ISUPTW, an international symposium, is
devoted to strengthening the collaboration among worldwide researchers and
promoting the development in ultrafast and terahertz science and technology.
The biennial symposium, initiated in 2002, has been held in Beijing, Shanghai,
Nanjing, Tianjin, Xi'an, Wuhan, Shanghai and Chongqing. It brings together
scientists, technologists, and students from more than 10 countries and typically
hosts 150-300 participants.
This year, the conference will be
held in Changsha from 23rd to 26th
April at Empark Grand Hotel
Changsha, organized by National
University of Defense Technology
(NUDT) and Optical Society of
America (OSA). We received 190
abstracts from 13 countries and
pushed our technical program to
work hard to complete the peer
review response on time. We thank all committees for their suggestions and
recommendations and all reviews for their good work. We hope you will enjoy the
technical program of this conference; we have numerous exciting talks lined up as
well as exhibits by many of the active companies in the field.
We would also like to invite you to enjoy and explore Changsha’s unique cultural
characters and beautiful cityscape.
Situated in the river valley along the lower reaches of the Xiang River, Changsha is
the capital city of Hunan Province. The recorded history of Changsha can be
traced back 3,000 years. Tomb relics from the primitive periods witnessing the
earliest human activities have been discovered in this region. During the Spring
2
and Autumn Period (770 B.C. - 476 B.C.), the area developed into an important
town within the State of Chu, (one of the seven warring states that existed before
China's unification by Emperor Qin). After Emperor Qin (the first feudal emperor in
China's history) unified the country, the town was set up as a county and later
became the capital city of a state in the early Han Dynasty (206 B.C. - 220). The
tomb excavation site of Mawangdui found in the eastern suburb of the city is a
family graveyard from that period. The most fantastic historical relic should be the
well-preserved mummified remains of
a Western Han Dynasty woman
excavated from the tombs. Some of
thousands of relics unearthed include
silk products, paintings, lacquer works,
potteries, bamboo slips used for
writing, weapons and herbs, all of
which are exhibited in Hunan Provincial
Museum.
In the dynasties that followed, the city experienced several expansions and during
China's Qing Dynasty (1644-1911), it has developed into the political, economic
and cultural center of Hunan Province.
Although not as ancient a capital city
as Beijing, Nanjing or Xian, Changsha
also has rich historical heritages
including old wall remains, tomb sites,
religious temples and buildings. What
earns the city its reputation among
tourists are two things. One is a great
man in China's recent history,
Chairman Mao Zedong and the other
is Yuelu Academy, a time-honored academic school perched on the scenic Yuelu
Mountain. Originally built in 976 during the Song Dynasty, the academy school
survived through the Yuan, Ming and Qing dynasties and is considered to be the
cradle of Huxiang Culture. (simply means the culture school in Hunan Province)
3
The village of Shaoshan, about 130
kilometers south-west of Changsha is
the hometown of Chairman Mao
Zedong. Today, the village has become
a memorial place for Chinese people to
remember this extraordinary man.
People erected a statue of the
Chairman and have preserved the
houses he lived as a tourist site. A
museum and other memorial spots in the scenic area create a kind of solemn
atmosphere. Many Chinese come to pay respect and visit here during the
memorial days.
In addition, the city was home to other
revolutionary leaders including Liu Shaoqi,
Huyaobang and former Chinese prime
minister, Zhu Rongji. Therefore, it acts as a
good place to learn more about China's
recent history.
Changsha people boast to be the best
gourmand of China and here people
spend a lot of time eating. Xiang Cuisine
is one of the Eight Cuisines in China and
has a fine and delicate appearance and
a hot & sour taste and the heavy and hot
taste is an equal competitor to the spicy
food of Sichuan. Street dining and
restaurants in the city make every visitor's
mouth hot. No matter the featured
snacks - 'Stinky Tofu' and 'Sisters'Rice
4
Balls' in Huogongdian (Fire Palace) or the
famous spicy shrimps at Nanmenkou, the
many types of delicious local food will
not disappoint any guests.
Changsha people are also renowned for
their acting and have created various
traditional folk art performances of their
own including the local operas,
storytelling, drum opera, acrobatics and other dramatic styles. Everyone can feel
their hospitalities and enthusiasm by their vigorous dances. Today, most of the
entertainment houses in the city
present dynamic and entertaining
performances featuring a blend of the
traditional essence and the modern
flare. The neon lights of KTV squares,
disco parlors, clubs and dancing
squares illuminate the city at night.
Dotted with all sorts of bars and pubs,
Jiefang Xilu, although not as
prosperous as Sanlitun Pub Street in
Beijing, has its own styles. Romantic and quiet bars, dynamic show bars, teahouses,
western style restaurants...People of all ages can find their ideal place to spend
their leisure time.
Welcome to ISUPTW 2018. May you have a fantastic time in Changsha!
5
The ISUPTW 2018 Committees
Honorary Chair:
Zejin Liu, National University of Defense Technology, China
General Chair:
Zengxiu Zhao, National University of Defense Technology, China
Co-chairs:
Xi-Cheng Zhang, University of Rochester, USA
Qihuang Gong, Peking University, China
International Committee:
1. Enrique Castro Camus, Centro de Investigaciones en Optica A.C., Mexico
2. Zenghu Chang, University of Central Florida, USA
3. Dajun Ding, Jilin University, China
4. Dianyuan Fan, Shenzhen University, China
5. Aaron Lindenberg, Stanford University, USA
6. Sergei Kozlov, ITMO University, Russia
7. Emma Pickwell-Macpherson, Warwick University, UK
8. Harald Schneider, Helmholtz-Zentrum Dresden-Rossendorf, Germany
9. Xuechu Shen, Shanghai Institute of Technical Physics, CAS, China
10. Zhengming Sheng, Shanghai Jiaotong University, China & University of
Strathclyde, UK
11. Alexander Shkurinov, Lomonosov Moscow State University, Russia
12. Masayoshi Tonouchi, Osaka University, Japan
13. Zhiyi Wei, Institute of Physics, CAS, China
14. Peiheng Wu, Nanjing University, China
15. Yirong Wu, The Institute of Electronics, CAS, China
16. Jianquan Yao, Tianjin University, China
17. Jianmin Yuan, National University of Defense Technology, China
18. Chao Zhang, University of Wollongong, Australia
19. Weili Zhang, Tianjin University, China
20. Xi-Cheng Zhang, University of Rochester, USA
21. Songlin Zhuang, University of Shanghai for Science and Technology, China
6
Technical Program Committee: 1. Juncheng Cao, Shanghai Institute of Microsystem and Information Technology
2. Chao Chang, Xian Jiaotong University,China
3. Hou-Tong Chen, Los Alamos National Laboratory, USA
4. Jian Chen, Nanjing University
5. Jing Chen, Beijing Institute of Applied Physics and Computational Mathematics
6. Ya Cheng, East China Normal University, China
7. Hongliang Cui, Chongqing Institute of Green and Intelligent Technology
8. Tiejun Cui, Southeast University, China
9. Jianmin Dai, Tianjin University, China
10. Wenhui Fan, Xi’an Institute of Optics and Precision Mechanics, CAS, China
11. Christoph P. Hauri, Paul Scherrer Institute, Switzerland
12. Jing Hou, National University of Defense Technology, China
13. Biaobing Jin, Nanjing University, China
14. Kiyong Kim, Maryland University (College Park), USA
15. Kyung Taec Kim, Gwangju Institute of Science & Technology (GIST)
16. Yutong Li, Institute of Physics, CAS, China
17. Jiansheng Liu, Shanghai Institute of Optics and Fine Mechanics, CAS, China
18. Weiwei Liu, Nankai University, China
19. Xiaojun Liu, Wuhan Institute of Physics and Mathematics, China
20. Yunquan Liu, Peking University, China
21. Peixiang Lu, Huazhong University of Science and Technology, China
22. Shengcai Shi, Purple Mountain Observatory, CAS, China
23. Wei Shi, Xi’an University of Technology, China
24. Hongqiang Wang, National University of Defense Technology, China
25. Li Wang, Institute of Physics, CAS, China
26. Heping Zeng, East China Normal University, China
27. Cunlin Zhang, Capital Normal University, China
28. Dongwen Zhang, National University of Defense Technology, China
29. Yaxin Zhang, University of Electronic Science and Technology of China, China
30. Yiming Zhu, University of Shanghai for Science and Technology, China
7
General Information
Conference Venue
ISUPTW 2018 is held at Empark Grand Hotel
Changsha
No. 199 Jintai Road, Kaifu District, Changsha, 410008,
P.R. China
Tel: (86) 731 8595 8888
Accessibility
Located in the north of Changsha within the close
proximity to some of Changsha's major historic spots,
Empark Grand Hotel sits beside the intersection of
Xiangjiang River and Liuyang River. It is only a
45-minute drive from the Changsha Huanghua airport (31km) to the hotel, a 40-minute drive from
Changsha South Railway Station (21km) to the hotel.
Onsite Registration
The registrants have the access to all conference sessions, plenaries, poster sessions and exhibition,
coffee breaks, three-day lunches (23 April and 26 April), welcome reception, conference banquet
and awards ceremony, conference program, internet wireless access, etc.
Hours and Places:
14:00-20:00 Monday, 23 April Lobby of 1st floor, Empark Grand Hotel
08:30-17:30 Tuesday, 24 April Lobby of 1st floor, Empark Grand Hotel
08:30-17:30 Wednesday, 25 April Lobby of 1st floor, Empark Grand Hotel
08:30-11:00 Thursday, 26 April Lobby of 1st floor, Empark Grand Hotel
Speaker Preparation
All meeting rooms will have a laptop for giving presentations. All presenters are requested to copy
your work to the laptop at least ten minutes prior to the session of your talk and confirm the display
settings with the audiovisual equipment being used at the session.
No shows of the oral presentation will be reported to conference management and these papers
will not be published.
Poster Preparation
THz poster session is scheduled at 17:10 - 18:30, 24 April and 17:15 - 18:30, 25 April. The poster
sessions of ultrafast phenomena are located in Room 2 and THz waves in Room 3, respectively.
Presenters should display the paper title and authors and affiliations on their posters of 90 cm
(width) x 120 cm (height). Authors should remain in the vicinity of the bulletin board for the
duration of the session to answer questions. Please note that poster papers are not supplied with
electricity or audiovisual equipment. Set-up/Tear-down
As a general rule, presenters should plan on posting their papers at least 1 hour prior to the poster
session and tearing down their papers within 30 minutes after the conclusion of the session.
8
Only papers that are presented at the conference will be published. Any "no-shows" will be
considered withdrawn from the conference and not included in the archival publication.
Exhibition
The ISUPTW 2018 Exhibitiopn is open to all attendees.
Location: Public area, 1st Floor, Empark Grand Hotel
09:00-18:00 Tuesday, 24 April 1st floor, Empark Grand Hotel
08:30-18:00 Wednesday, 25 April 1st floor, Empark Grand Hotel
08:30-11:30 Thrusday, 26 April 1st floor, Empark Grand Hotel
Map
9
10
Group Photo
The west parking lot of the Empark Grand Hotel after the plenary session on the morning of 24,
April, 2018.
Best Student Paper Award
Student paper competition is limited to full time students. To win the prize, the author must be the
first author and the presenter of either oral or poster presentation, which will be evaluated by
Program Committee Members, based on not only the submitted abstract content, but also the
quality of the presentation. The winners will be announced and awarded certificates with prize in
cash (RMB ¥1500/recipient) at conference banquet and awards ceremony on 25 April.
Sponsored by
Meals
Lunches
23 April 11:30-13:30, Golden Centuby Chinese Restaurant, 1st floor, Empark Grand Hotel
24 April 12:00-13:30, Golden Centuby Chinese Restaurant, 2nd floor, Empark Grand Hotel
25 Arpil 12:00-13:30, Golden Centuby Chinese Restaurant, 2nd floor, Empark Grand Hotel
26 Arpil 12:00-13:30, Golden Centuby Chinese Restaurant, 2nd floor, Empark Grand Hotel
Dinners
24 April 18:30-20:00, Golden Centuby Chinese Restaurant, 2nd floor, Empark Grand Hotel
Welcome Reception
23 April 18:00-20:00 Golden Centuby Chinese Restaurant, 2nd floor, Empark Grand Hotel
Conference banquet and awards ceremony:
25 April, 18:30-20:00, the West Lake Floor (the largest restaurant in Asian)
Waiting for the bus after the poster session in the platform before the hotel gate at 18:30 of 25
April.
Wifi Connection Guide
1. Select the Wi-Fi network named Empark grand hotel
2. No password
11
Daily Schedule
Tuesday, 24 April, 2018
08:30 AM 08:50 AM Opening Ceremony (Room 1)
08:50 AM 10:20 AM TuA • Plenary Session I (Room 1)
10:20 AM 10:50 AM Coffee Break and Take Photos
10:50 AM 12:00 PM TuB • Extreme Terahertz Science and Technology I (Room 1)
10:50 AM 12:00 PM TuC • Novel Terahertz Detectors (Room 3)
10:50 AM 12:00 PM TuD • Ultrafast Phenomena in Micro and Nano-Structures (Room 2)
01:30 PM 03:20 PM TuE • Extreme Terahertz Science and Technology II (Room 1)
01:30 PM 03:20 PM TuF • Terahertz in Biomedical Systems (Room 3)
01:30 PM 03:20 PM TuG • High-Field Physics and Attosecond Science I (Room 2)
03:40 PM 05:10 PM TuH • Terahertz Spectroscopy and Imaging I (Room 1)
03:40 PM 05:10 PM TuI • Terahertz Science and Technology in Micro and Nano-Structures I (Room 3)
03:40 PM 05:10 PM TuJ • High-Field Physics and Attosecond Science II (Room 2)
05:10 PM 06:30 PM TuK • Poster Session I (Ultrafast in Room 2 and THz in Room 3)
Wednesday, 25 April, 2018
08:30 AM 10:00 AM WA • Plenary Session II (Room 1)
10:20 AM 12:00 PM WB • Terahertz Application (Room 1)
10:20 AM 12:00 PM WC • Terahertz Science and Technology in Micro and Nano-Structures II (Room 3)
10:20 AM 12:00 PM WD • High-Field Physics and Attosecond Science III (Room 2)
01:30 PM 03:00 PM WE • Plenary Session III (Ball Room 1)
03:20 PM 05:00 PM WF • Terahertz QCL (Room 1)
03:20 PM 05:00 PM WG • Terahertz Science and Technology in Micro and Nano-Structures III (Room 3)
03:20 PM 05:00 PM WH • Ultrahigh Intensity Laser and Its Application (Room 2)
05:15 PM 06:30 PM WI • Poster Session II (Ultrafast in Room 2 and THz in Room 3)
Thursday, 26 April, 2018
08:30 AM 10:00 AM ThA • Plenary Session IV (Room 1)
10:20 AM 12:00 PM ThB • Terahertz Spectroscopy and Imaging II (Room 1)
10:20 AM 12:00 PM ThC • Terahertz Science and Technology in Micro and Nano-Structures IV (Rm 3)
10:20 AM 12:00 PM ThD • Terahertz Spectroscopy and Imaging III (Room 2)
12
Explanation of Session Codes
Day of the Week Presentation Designation Session Designation
The first letter of the code designates the day of the week. Each day begins with the letter A in the
second element and continues alphabetically through the session day. The lettering then restarts with
each new series. The number on the end of the code (separated from the session code with a period)
signals the position of the talk within the session (first, second, third, etc.).
For example, a presentation coded MA4 indicates that this paper is being presented on Monday (M) in the
first session (A) and is the fourth paper (4) presented in that session.
MA4
13
Plenary Presentations
Tuesday, April 24, 2018, TuA1 8:50, Room 1
Nonlinear THz spectroscopy of graphene and GaAs quantum wells
using a free-electron laser
H. Schneider, Institute of Ion-Beam Physics and Materials Research,
Helmholtz-Zentrum Dresden-Rossendorf, Dresden, GERMANY
This talk reviews some recent experiments using FEL-based intense narrow-band terahertz fields, in particular
pump-induced optical anisotropy and nonlinear four-wave mixing in graphene, and dressing of excitons,
exciton-polaritons, and intersubband transitions in GaAs quantum wells.
Harald Schneider received his diploma (master) degrees in
physics and in mathematics from the University of Tübingen,
Germany in 1985 and completed his Ph. D. at the Max-Planck
Institute for Solid-State Research, Stuttgart, Germany, in 1988. In
1989 he moved to the Fraunhofer-Institute for Solid State Physics,
Freiburg, Germany, and in 2005 to the Helmholtz-Zentrum
Dresden-Rossendorf, Dresden, Germany, where he is currently
working as a department head. He has been faculty member at
the University of Freiburg, Germany, since 2003. He was Visiting
Overseas Chair Professor at the Shanghai Jiao Tong University
from 2010 to 2013 and was selected for "1000 Talents Plan"
(Foreign Expert Program) of the Chinese Central Government in
2013. His research interests include optoelectronic properties of
semiconductors, ultrafast and free-electron laser based infrared
and THz spectroscopy, and detectors for the infrared and THz
regimes. He was awarded the 2001 German Science Foundation
Award for the development of infrared cameras with highest thermal resolution. He served as committee
member in more than 20 international conferences, gave more than 40 invited conference talks, and
co-authored more than 300 publications.
14
Tuesday, April 24, 2018, TuA2 9:35, Room 1
Information Metamaterials and Metasurfaces
T. Cui, State Key Laboratory of Millimeter Waves, Southeast University, Nanjing, Jiangsu, CHINA
In this presentation, the coding, digital, and field programmable metamaterials and metasurfaces are
systematically introduced with particular emphases on recently new developments. The future trend of
information metasurfaces and metamaterials is also predicted.
Prof. Tie Jun Cui received the Ph.D. degree in Xidian University,
Xi’an, China, in 1993. In March 1993, he joined the Department of
Electromagnetic Engineering, Xidian University, and was
promoted to an Associate Professor in November 1993. From
1995 to 1997 he was a Research Fellow with Institut fur
Hochstfrequenztechnik und Elektronik (IHE) at the University of
Karlsruhe, Germany. In July 1997, he joined Center for
Computational Electromagnetics, Department of Electrical and
Computer Engineering, University of Illinois at Urbana-Champaign,
first as Postdoc and then Research Scientist. In September 2001,
he became a Cheung-Kong Professor with Department of Radio
Engineering, Southeast University, Nanjing, China. From 2013, he
has been a Representative of People’s Congress of China.
Dr. Cui is the first author of books Metamaterials – Theory, Design,
and Applications (Springer, 2009) and Metamaterials: Beyond
Crystals, Noncrystals, and Quasicrystals (CRC Press, 2016). He has published over 400 peer-review journal
papers in Science, PNAS, Nature Communications, Light Science & Applications, Physical Review Letters,
Advanced Materials, etc., which have been cited by more than 18500 times (H-Factor 70). Dr. Cui was
awarded a Research Fellowship from the Alexander von Humboldt Foundation, Bonn, Germany, in 1995. He
received Young Scientist Award from the International Union of Radio Science (URSI) in 1999, National Science
Foundation of China for Distinguished Young Scholars in 2002, and Special Government Allowance awarded
by Department of State, China, in 2008. He received the First Prize of Natural Science Awards from Ministry of
Education, China, in 2011, the Second Prize of National Natural Science Awards, China, in 2014, and the First
Prize of Military Science and Technology Progress Awards, China, in 2016. His research has been selected as
“Optics in 2016” by Optics and Photonics News Magazine (OSA), “10 Breakthroughs of China Optics in 2016”,
“10 Breakthroughs of China Science in 2010”, “Best of 2010” in New Journal of Physics, and Research
Highlights in many academic journals. His work has been reported by Nature News, Science, MIT Technology
Review, Scientific American, New Scientists, etc.
15
Wednesday, April 25, 2018, WA1 8:30, Room 1
Progress in ultrafast terahertz scanning tunneling microscopy
F.A. Hegmann, University of Alberta, Edmonton, Alberta, CANADA
The ability to directly probe ultrafast phenomena on the nanoscale is essential to our understanding of
excitation dynamics on surfaces and in nanomaterials. Recently, a new ultrafast scanning tunneling
microscope (STM) technique that couples terahertz (THz) pulses to the scanning probe tip of an STM was
demonstrated (THz-STM), showing photoexcitation dynamics of a single InAs nanodot with simultaneous 0.5
ps time resolution and 2 nm spatial resolution under ambient conditions. Operation of THz-STM in ultrahigh
vacuum now makes it possible to spatially-resolve subpicosecond dynamics of single molecules and silicon
surfaces with atomic precision. This talk will discuss how THz-STM works, recent progress, and how THz-STM
can provide new insight into ultrafast dynamics on the atomic scale, which is essential for the development of
novel silicon nanoelectronics and molecular-scale devices operating at terahertz frequencies.
Frank Hegmann received his PhD in Physics from McMaster
University in 1994 and then worked as a postdoctoral researcher
at the Center for Terahertz Science and Technology at the
University of California, Santa Barbara. In 1997, he started as an
assistant professor in the Department of Physics at the
University of Alberta studying ultrafast dynamics in materials
using time-resolved terahertz (THz) pulse spectroscopy. He is
currently a Professor in Physics and AITF Strategic Chair in
Terahertz Science and Technology with research interests in THz
pulse spectroscopy of nanomaterials, ultrafast imaging, ultrafast
THz-STM, terahertz nonlinear dynamics, and biological effects of
intense THz pulses.
16
Wednesday, April 25, 2018, WA2 9:15, Room 1
High energy and high efficiency chirped pulse amplifiers
in 10 PW laser
X. Liang, Z. Gan, W. Li, L. Yu, Y. Liu, C. Wang, Y. Hang, Y. Leng, R. Li, Z. Xu,
Shanghai Inst of Optics & Fine Mechanics, Shanghai, Shanghai, CHINA
A high energy and efficiency amplifier in SULF laser was demonstrated with output energy of 339J, which
contained a Ti:Sapphire crystal with diameter of 235mm. After compression, the peak power of 10.3 PW was
achieved.
Prof. Liang received her Ph.D degree in 2001 and joined Shanghai
Institute of Optics and Fine Mechanics in 2003. Her current
research is mainly in the fields of laser technologies, diagnosis
and applications, coherent beam combining and nonlinear optics.
Recently, she is engaging in 10 PW laser of SULF project.
17
Wednesday, April 25, 2018, WE1 13:30, Room 1
Recent Progress on terahertz source, modulation and its applications
Jianquan Yao, Institute of Laser and Optoelectronics,
Key Laboratory of the Ministry of Education on Optoelectronic Information Technology,
School of Precision Instruments and Optoelectronics Engineering, Tianjin University, Tianjin, CHINA
The development of terahertz (THz) source and modulation facilitates a wider variety of applications. This talk
addresses our recent researches on THz sources based on THz parametric oscillator and difference frequency
generation and proposes a novel modulation technology that combines the modulation of both the THz
sources and devices. The works of THz applications in biomedical diagnostics by transmission imaging,
attenuated total reflection imaging and metamaterial based biosensors are described as well, followed by
summarization of the recent progress and prediction of the future trends of THz technology.
Jianquan Yao, member of Chinese Academy of Science, professor
of Tianjin University, is engaged in the researches on nonlinear
optics, physics and technology of laser and THz, and micro-nano
optoelectronic materials. He has served as a visiting professor in
Stanford University, Princeton University, University of
Pennsylvania in USA, and some other universities in UK, France
Germany, Russian, Hong Kong and Taiwan. Professor Yao’s major
achievements are on the laser and optical frequency conversion
technology. He presented and developed the theory and method
of precise calculation of the optimum phase matching for three
wave interactions with nonlinear optical biaxial crystals. His
papers were named “Yao and Fahlen Technology”. He advanced
“Gaussian like distribution” of laser resonant theory. He
developed the theory of laser frequency doubling under high
conversion efficiency and new method with quasi-CW pumping.
He developed an intracavity frequency doubled Nd:YAG laser
whose output power was up to 150 Watts, and this laser source was used to establish laser three dimension
scanning photography system. He invented the dye and Titanium sapphire tunable laser systems pumped by
quasi-CW green laser source. He established a quasi-CW pumped—tunable laser technical system, making
important contributions to the development of the new solid-state laser and tunable laser technologies.
Recently, he focuses on high power laser diode pumped solid state laser, tunable laser, frequency conversion
by quasi-phase matching technology using periodical poled crystals for SHG and OPO, as well as THz wave
generation by DFG and TPO and some other nonlinear optical methods. He was awarded Second Prize for
National Invention et al. He published three books: “Nonlinear Optical Frequency Conversion and Tunable
Laser Technology” (Science Press, 1995), “All Solid State Laser and Nonlinear Optical Frequency Conversion
Technology” (Science Press, 2007), and “Nonlinear Optics and Solid-State Lasers: Advanced Concepts,
Tuning-Fundamentals and Applications (Springer Series in Optical Sciences, 2012). He was elected Member of
the Chinese Academy of Sciences in 1997.
18
Wednesday, April 25, 2018, WE2 14:15, Room 1
Generation, Characterization, and Applications of
Single-cycle Laser Pulses
K. Kim, Institute for Basic Science, Gwangju, KOREA (THE REPUBLIC OF)
New methods for the generation and characterization of a single cycle laser pulse are presented. The
applications of the single cycle laser pulse on high harmonic generation and frustrated tunneling ionization
are also discussed.
Prof. Kyung Taec Kim has started his research carrier through his
Master and Ph. D. degree courses at KAIST under the supervision
of Prof. Chang Hee Nam. He has proposed an attosecond pulse
compression using x-ray filters and developed techniques for the
characterization of the electron wave packet produced by the
attosecond pulses during his degree courses. After he obtained Ph.
D, he participated in the project to build the PW laser facility in
the Advanced Photonics Research Institute at Gwangju Institute of
Science and Technology (GIST) in Korea. In 2010, he has joined
Paul Corkum’s research group at the National Research Council in
Canada. He developed optical techniques to measure the
space-time coupling of attosecond pulses and arbitrary optical
waveforms of light pulses. Prof. Kyung Taec Kim is now a group
leader of the attosecond science group in the center of the
relativistic laser science of the institute of basic science at GIST in
Korea.
19
Thursday, April 26, 2018, ThA1 8:30, Room 1
Recent Development on THz Aqueous Photonics
X. Zhang, U of Rochester, The Institute of Optics, Rochester, New York, UNITED STATES
We demonstrated THz wave generation from liquid water in spite of its infamously strong absorption
characteristics. It is reasonable to expect that liquids might have unique properties if they could be harnessed
as THz sources.
Xi-Cheng Zhang is M. Parker Givens Chair of Optics at The Institute
of Optics, a foremost institution in optics and optical physics
research and education, in the University of Rochester, NY, USA.
He was the director of The Institute from Jan. 2012 to June 2017.
Prior to joining UR on 1 January 2012, he pioneered world-leading
research in the field of ultrafast laser-based terahertz technology
and optical physics at Rensselaer Polytechnic Institute, Troy, NY
(1992-2012). At RPI, he was the Eric Jonsson Professor of Science;
Acting Head at the Department of Physics, Applied Physics &
Astronomy; and Founding Director of the Center for THz
Research. He is co-founder of Zomega Terahertz Corp. With a
B.S. (1982) from Peking University, he earned the Ph.D. degree
(1986) in Physics from Brown University, RI.
He is a Fellow of OSA, SPIE, AAAS, APS, and IEEE. Xi-Cheng¹s
recent honors and awards include: Australian Academy of Science Selby Fellow (2017); IRMMW-THz Kenneth
Button Prize (2014); OSA William F. Meggers Award (2012) and IEEE Photonics Society William Streifer
Scientific Achievement Award (2011). He holds 29 U.S. patents, and is a prolific author, researcher and
speaker. He serves as the editor in chief of Optics Letter for OSA since 2014.
20
Thursday, April 26, 2018, ThA2 9:15, Room 1
Ultrafast light manipulation using photonic micro/nano-structures
Qihuang Gong, Jianjun Chen, Zheng Chai, Hong Yang and Xiaoyong Hu
State Key Laboratory for Mesoscopic Physics, Department of Physics,
Peking University, Beijing 100871, P. R. CHINA
Micro/nano photonic structures permit remarkable control of the propagation of light. The micro/nanoscale
ultrafast light manipulation paves the way for the realization of various nanoscale integrated photonic devices,
which construct the essential basis of ultrahigh-speed and ultrawide-band information processing chips.
Moreover, for practical chip-integration applications, several significant features, including on-chip trigger,
ultrafast response, ultralow energy consumption, and wideband (or multiple-wavelength) operation, are
stringently required.
In this presentation, a selection of recent results will be presented.
we realized an ultrafast, ultralow power, on-chip-triggered 2x2
all-optical switch with multiple operating wavelengths based on
plasmon–photon hybrid nanostructures coated nonlinear
multi-component nanocomposite material formed directly in
integrated photonic circuits. Low threshold pump intensity of 450
kW/cm2, fast response of 63 ps, and multiple operating
wavelengths were realized simultaneously. An ultralow-power
all-optical logic data distributor with dual address bits is also
realized, based on a large nonlinearity enhancement occurs in the
nanocomposite material through resonant excitation via an
upconversion radiative-transfer process, which ensures an
ultralow operating threshold control intensity of 10 kW/cm2. An
ultrafast response time of several picoseconds is simultaneously
maintained based on structural defects inducing ultrafast decay of
excited-state carriers. Based on tunable Fano resonance or PIT of metallic nanostructures, ultrafast
modulations on light transmission were also demonstrated. Moreover, ultracompact plasmonic devices
including SPP unidirectional generator, splitter and others were experimentally demonstrated.
Professor Qihuang Gong is the Academician of Chinese Academy of Science, Boya Chair Professor of Peking
University, Cheung Kong Professor of Physics at Peking University, China, where he is the Founding Director of
the Institute of Modern Optics. He also serves as the Vice President of Peking University. In addition, Prof.
Gong serves as Director of Academic committee of the State Key Laboratory for Artificial Microstructure and
Mesoscopic Physics. Prof. Gong is member of the Chinese Academy of Sciences and member of the world
academy of sciences.
His current research interests are in ultrafast optics and spectroscopy, nonlinear optics, and mesoscopic
optical devices for applications in optical information processing and communication. He has authored more
than 300 articles which have received approximately 10,000 citations, with an H-index of 39. His group has
been awarded 25 patents. Prof. Gong has received numerous awards, including The State Natural Science
Award (2nd -Class), the Beijing City Science and Technology Award (1st -Class), the Science and Technology
21
Award ( 1st-Class) of Ministry of Education, the Chinese Physical Society’s Rao Yutai Physics Prize, the Wang
Daheng Science and Technology Prize given by the Chinese Optics Society and HLHL Science and Technology
Award. He has won the Youth Scholar Award (Physics) of the Hong Kong Qiushi Foundation, and the Science
and Technology Award for China Youth. He has also been the honored winner of special government
allowances, and he was named one of the Top 10 Excellent Youths of Beijing. He is a Fellow of Optical Society
of America (OSA), Fellow of Institute of Physics (IoP) and Fellow of Chinese Optical Society (COS).
Prof. Gong is currently the chief scientist of the National 973 Project (the Chinese National Basic Research
Program), Principal of the creative research group of the National Natural Science Foundation of China, the
group leader for the creative research group of the Ministry of Science . Prof. Gong has served as a topical
editor for Optics Letters, advisor editor of Chemical Physics, Chemical Physics Letters, Advanced Optical
Material, Optics Communications, Annalen der Physik and associate editor-in-chief of Chinese Physics B,
Chinese Optics Letters, Chinese Optics and Applied Optics (in Chinese), Acta Physica Sinica (in Chinese) and
Quantum Electronics (in Chinese). He serves as the President of the Chinese Optical Society, Vice President of
the Chinese Physical Society. He is the Standing Committee member of China Association for Science and
Technology. Prof. Gong is the vice chair for ICO (International Commission for Optics) and vice chair for IUPAP
C17 (Quantum Electronics).
22
TuA Plenary session I
Tuesday, April 24, 2018, TuA 8:50--10:20, Room 1
Xuechu Shen,Shanghai Institute of Technical Physics, CAS, China, Presider
TuA1 8:50, plenary
Nonlinear THz spectroscopy of graphene and GaAs quantum wells using a free-electron laser
Harald.Schneider, Institute of Ion-Beam Physics and Materials Research, Helmholtz-Zentrum
Dresden-Rossendorf, Dresden, GERMANY|
This talk reviews some recent experiments using FEL-based intense narrow-band terahertz fields, in
particular pump-induced optical anisotropy and nonlinear four-wave mixing in graphene, and dressing of
excitons, exciton-polaritons, and intersubband transitions in GaAs quantum wells.
TuA2 9:35, plenary
Information Metamaterials and Metasurfaces
Tie Jun. Cui, State Key Laboratory of Millimeter Waves, Southeast University, Nanjing,Jiangsu, CHINA|
Metamaterials are traditionally described by effective medium parameters due to subwavelength scales
of unit particles. The continuous nature of the medium parameters makes the traditional metamaterials
behave as analog metamaterials. Recently, the concept of coding metamaterials or metasurfaces has
been proposed, in which metamaterials are characterized by 1-bit digital coding particles of ‘0’ and ‘1’
with 180° phase difference, or 2-bit digital coding particles of ‘00’, ‘01’, ‘10’, and ‘11’ with 90° phase
difference, etc. It was demonstrated that the electromagnetic waves can be manipulated by changing the
digital coding sequences. The coding particles provide a link between the physical world and digital
world, leading to digital metamaterials and even field programmable metamaterials, which can be used
to control the electromagnetic waves in real time. The digital coding representation of metamaterials or
metasurfaces allows the concepts and signal processing methods in information science to be introduced
to the physical metamaterials, realizing extreme controls to the electromagnetic waves, such as Shannon
entropy, convolution theorem, and addition theorem. Such studies set up the foundation of information
metamaterials and metasurfaces. In this manner, metamaterials are not only the effective materials, but
can also be real-time information processing systems (e.g. new-concept radar, programmable imaging
and hologram, and new-concept communication systems). In this presentation, the coding, digital, and
field programmable metamaterials and metasurfaces are systematically introduced with particular
emphases on recently new developments. The future trend of information metamaterials is also
predicted.
23
TuB Extreme terahertz science and technology I
Tuesday, April 24, 2018, TuB 10:50--12:00, Room 1
Alexander Shkurinov, M. V. Lomonosov Moscow State University, Presider
TuB1 10:50 Keynote
Sub-cycle THz nonlinear optics using large-aperture photoconductive antennas
Tsuneyuki. Ozaki, INRS-EMT, Varennes, Quebec, CANADA|
Using intense quasi-half-cycle terahertz pulses from a large-aperture photoconductive antenna, we
demonstrate sub-cycle terahertz nonlinear optics. Experiments reveal strong THz transmission bleaching
and the generation of high frequency components.
Tsuneyuki Ozaki is a Professor at the INRS (Canada), the former Director of the Advanced Laser Light
Source (2006 to 2012), and the current Chair of Commission 17 “Laser Physics and Photonics” of IUPAP.
His main research interests include high-intensity THz sources and their applications, and intense
high-order harmonics.
TuB2 11:20 Invited
Single-shot electro-optic detection for intense terahertz pulses
Shixiang. Xu, Shenzhen University, Shenzhen, GuangDong, CHINA|
We report a single-shot terahertz common-path spectral interferometer based on electro -optic
sampling, which can improve experimentally the measured signal-noise ratio (SNR) by 11.4 times
compared with Mach-Zehnder interferometer.
TuB3 11:40 Invited
Strong-field Terahertz Generation and its Applications
Xiaojun. Wu, S. Chai, D. Kong, C. Ruan, J. Miao, Beihang University, Beijing, CHINA|J. Ma, B. Zhang, S. Li, Y.
Li, Beijing National Laboratory for Condensed Matter Physics, Institute of Physics, Chinese Academy of
Sciences, Beijing 100190, China, Beijing , CHINA|B. Zhang, S. Li, School of Physical Sciences, University of
Chinese Academy of Sciences, Beijing 100049, China, Beijing , CHINA|
We demonstrate generation of 0.2 mJ terahertz pulses with >0.4% optical-to-terahertz efficiency
delivering a focused electric field of 4 MV/cm at 0.3 THz in lithium niobate at room temperature driven
by chirped femtosecond laser pulses.
24
TuC Novel terahertz detectors
Tuesday, April 24, 2018, TuC 10:50--12:00, Room 3
Wei Shi, Xi’an University of Technology, China, Presider
TuC1 10:50 Keynote
High-sensitivity and fast terahertz bolometric detection by MEMS resonators
Kazuhiko. Hirakawa, University of Tokyo, Meguro-ku, Tokyo, JAPAN|
Using a novel thermomechanical transduction scheme. We have developed an uncooled, sensitive, and
fast THz bolometer by using a doubly clamped GaAs MEMS beam resonator as a sensitive thermistor.
The MEMS bolometer achieves an operation bandwidth of several kHz, which is ~100 times faster than
other uncooled thermal sensors.
Kazuhiko Hirakawa received the B.E., M.E., and Ph.D. degrees in electronic engineering in 1982, 1984,
and 1987, respectively, from University of Tokyo. He is currently a professor at Institute of Industrial
Science, University of Tokyo. He was a visiting researcher at Princeton University for 1991-1993 and a
visiting professor at Laboratoire Pierre Aigrain, Ecole Normale Superieure in 2006. His research
interests include electron transport and terahertz photodynamics of quantum nanostructures.
TuC2 11:20 Invited
Characterization of field-effect terahertz detectors by using terahertz time-domain spectroscopy
Hua. Qin, Y. Yu, J. Sun, Suzhou Inst. of Nano-tech & Nano-bionics, Suzhou, JiangSu, CHINA|
Antenna-coupled field-effect transistors (FETs) are being developed as sensitive and fast terahertz
detectors. We report preliminary results on characterization of AlGaN/GaN-FET detectors by using
terahertz time-domain spectroscopy.
TuC3 11:40 Invited
Tailoring structure imperfection in ZnTe bulk crystals and improving the terahertz response
Yadong. Xu, J. Dong, Northwestern Polytechnical University, Shaanxi, CHINA|
High singularity ZnTe in dimension of 60 mm are grown in this work by temperature gradient solvent
method. The post growth processing including surface modification and wafer annealing were
performed for further THz response optimization.
25
TuD Ultrafast phenomena in micro and
nano-structures
Tuesday, April 24, 2018, TuD 10:50--12:00, Room 2
Jing Chen, Beijing Institute of Applied Physics and Computational Mathematics, China, Presider
TuD1 10:50 Keynote
Ultrafast Dynamic and Nonlinear Optics in Metamaterial/Plasmonic Structures
Kam. Sing. Wong, Hong Kong Univ of Science & Technology, Kowloon, HONG KONG|
We will report on our study of femtosecond temporal delays for laser pulses pass through
subwavelength metallic hole arrays and multipolar effects in the optical active second harmonic
generation (SGH) for sawtooth chiral metamaterials .
Kam Sing WONG received the BSc (Hons.) degree (1983) in physics from King’s College, University of
London, London, U.K., in 1983 and the D. Phil degree (1987) in solid-state physics from Clarendon
Laboratory, University of Oxford, Oxford, U.K., in 1987.He joined the Physics Department of Hong Kong
University of Science and Technology (HKUST) in 1991 as the founding faculty and currently a full
professor at the department. His main research interests include ultrafast lasers and nonlinear optics,
time-resolved spectroscopy, semiconductor and polymer physics, photonic crystal and plasmonics. He
has published over 200 peer-reviewed journal publications, 4 patents, total citations over 7000 and
h-index of 45.
TuD2 11:20 Invited
Ultrafast Plasmons Probed by Photoemission Electron Microscopy
Quan. Sun, K. Ueno, H. Misawa, Hokkaido University, Sapporo, HOKKAIDO, JAPAN|H. Misawa, National
Chiao Tung University, Hsinchu, TAIWAN|
The near field and dynamics of surface plasmons are probed by photoemission electron microscopy. In
particular, we reveal plasmon interaction in strong coupling region and observed ultrafast dynamics of
plasmons in the coupled plasmonic systems.
TuD3 11:40 Invited
Nitride based quantum dot single photon source
Mo. Li, China Academy of Engineering Physics, Mianyang, CHINA|
Nitride based nanowire quantum dots (NQDs) as single photon sources (SPS) have attracted lots of
research interests with a wide wavelength range from visible to near-infrared. Here we presented
InGaN/GaN NQDs fabricated by top-down method and selective area grown, which is promising for
integrated chip-scale SPS. Based on that structure, hyperbolic metamaterial was proposed to enhance
the performance of InGaN/GaN NQDs SPS, such as the spontaneous emission rate and photon extraction
efficiency. Our research provides a novel idea for high-frequency, high-brightness and directional
InGaN/GaN NQDs SPS.
26
TuE Extreme terahertz science and technology II Tuesday, April 24, 2018, TuE 13:30--15:20, Room 1
Peng Liu, Shanghai Inst of Optics and Fine Mech, China, Presider
TuE1 13:30 Keynote
>mJ terahertz radiation sources from intense laser-foil interactions
Yutong. Li, Inst Physics, Chinese Academy Sciences, Beijing, BEIJING, CHINA|
Terahertz radiation with energies up >1 mJ generated by transition radiation of intense laser-accelerated
electron beams crossing a foil has been demonstrated. The source will provide opportunities for studying
nonlinear THz-matter interactions.
Yutong Li studies intense laser plasma interactions, laser-driven particle and radiation sources, laboratory
astrophysics. He has published more than 150 papers, included 9 in PRL and 2 in Nature Physics. He has
won awards, including the Ten Thousand Talent Program, Distinguished Young Scholar of National
Natural Science Foundation. etc.
TuE2 14:00 Invited
High-power THz radiation from two-color laser filamentation at low pressures
Y. Yoo, D. Jang, Kiyong. Kim, University of Maryland at College Park, College Park, Maryland, UNITED
STATES|Y. Yoo, Thorlabs Imaging Systems, Sterling, Virginia, UNITED STATES|
We have studied THz emission from elongated, two-color-laser filamentation with various gas species
and pressures. We observe enhanced THz radiation at low gas pressures with a maximum laser-to-THz
conversion efficiency of 0.1%.
TuE3 14:20 Invited
Wavelength Scaling of Terahertz Wave Generation from Laser-Induced Air Plasma
Cunlin. Zhang, Capital Normal University, Beijing, CHINA|
We examine the terahertz (THz) emission from air filament driven by two-color lasers with relatively
longer wavelengths than 800 nm. The THz energy dependence on the input laser energy increases more
rapidly with a longer laser wavelength, and the scaling laws of THz energy as a function of fundamental
wavelength vary for different optical powers.
TuE4 14:40 Invited
Theoretical and experimental studies on THz Radiation via two-color laser scheme
Weimin. Wang, Chinese Academy Sciences Inst Physics, Beijing , CHINA|
Our two theoretic reports predicted efficient THz generation with new frequency ratios 1:4, 2:3, etc.
Recently, this prediction has been verified by our experiments for the first time.
TuE5 15:00 Invited
Effective control of strong terahertz radiation from femtosecond laser produced air plasmas
Yanping. Chen, Shanghai Jiao Tong University, Shanghai, CHINA|
We investigated strong terahertz radiation from a two-color laser-induced air-plasma. An effective
control of waveform, spatial distribution and polarization of such terahertz pulse is demonstrated.
27
TuF Terahertz in biomedical systems
Tuesday, April 24, 2018, TuF 13:30--15:20, Room 3
Chao Chang, Xian Jiaotong University, China, Presider
TuF1 13:30 Keynote
Terahertz in vivo skin imaging
Emma. Pickwell-MacPherson, University of Warwick, Warwick, UNITED KINGDOM|Q. SUN, J. Wang,
Electronic Engineering, Chinese University of Hong Kong, Hong Kong, HONG KONG|
In this work we present recent in vivo studies of skin. We show how the THz response of skin is affected
by occlusion time, pressure applied to the skin, and skin treatments.
Dr Pickwell-MacPherson completed both her undergraduate and graduate degrees at the University of
Cambridge (2001 and 2005 respectively). She moved to the Chinese University of Hong Kong in 2006 to
set up her own Terahertz research group. Her research aims to improve terahertz imaging and
spectroscopy techniques for non-invasive diagnosis and monitoring of skin conditions including (but not
limited to) skin cancer. Dr Pickwell-MacPherson joined the Physics Department at Warwick University, UK
in October 2017 and has won a Wolfson Merit award from the Royal Society to support her research in
the UK.
TuF2 14:00 Invited
A terahertz microfluidic chip for ultra-trace measurement of solution
Kazunori. Serita, E. Matsuda, K. Okada, H. Murakami, I. Kawayama, M. Tonouchi, Osaka University, Suita,
OSAKA, JAPAN|
We developed a terahertz microfluidic chip with a few arrays of split ring resonators. The obtained
resonance spectrum shows the high-sensitive frequency shift to detect femtomol of solutes in sub
nanoliter of solution.
TuF3 14:20 Invited
High-sensitive label-free biosensing from metamaterials
Biaobing. Jin, Nanjing University, Nanjing, JIangSu, CHINA|
We demonstrated our recent works on label-free THz biosensing from metamaterial.
TuF4 14:40 Invited
Terahertz spectroscopy of neurodegenerative diseases: the correlation between terahertz biophysics
and pathological analysis
Liguo. Zhu, Y. Zou, J. Li, Q. Liu, China Academy of Engineering Physics, Mianyang, SICHUAN, CHINA|
In this talk, I'll review and present our recent studies on THz spectroscopy of neurodegenerative diseased
brain tissue and living cell. The well-matched correlation between THz biophysical properties and
pathological analysis will also be discussed.
TuF5 15:00 Invited
The research on THz application in biomedical diagnosis
Yuye. Wang, Tianjin University, TIANJIN, TianJin, CHINA|
THz imaging of different degrees of experimental traumatic brain injury (TBI) has been demonstrated in
fresh slices of rat brain tissues. The high absorption region in THz images corresponded well with the
injured area in visible images and magnetic resonance imaging results. The distinguishable mechanism
by THz wave was studied, which could be attributed to the different water contents and probable
hematoma components distribution rather than intrinsic cell intensity.
28
TuG High-field physics and attosecond science I
Tuesday, April 24, 2018, TuG 13:30--15:20, Room 2
Ri Ma, Jilin University, China, Presider
TuG1 13:30 Keynote
Tuning femtosecond laser from visible to mid-infrared range
Zhiyi. Wei, Institute of Physics, CAS, Beijing, CHINA|
Efficient optical parametrical oscillators and amplifiers were researched with different nonlinear crystals
such as LBO, BBO, BiBO, KTA and SiC. Laser power up to 1.9W in the range from 688 to 1057nm, 2.32W
in the range from 1.41-1.71m, 1.3W in the range from 2.61 to 3.84 m, and the energy up to 520J at 2.8m
were obtained, corresponding to the maximum efficiency as high as 30%.
Zhiyi Wei obtained his Ph.D degree in 1991. After two years postdoctoral fellow at Sun Yat-Sen University
in China, he worked at the Rutherford Appleton Lab in UK, the Chinese University of Hong Kong, the
Hong Kong University of Science and Technology, University of Groningen in the Netherland as a visiting
scholar and postdoc during 1993 to 1997. He joined in the Laboratory of Optical Physics, Institute of
Physics, Chinese Academy of Sciences (CAS) in 1997. From April 2000 to Sept 2002, he also worked at the
Advanced Industrial Science and Technology (AIST) in Japan as a NEDO researcher. His research interests
focus on ultrafast ultraintense laser technology. Up to now, he has published more than 200
peer-reviewed papers. He has awarded by the State Natural Science Award (2nd-Class), the excellent
achievements (team) and contributions (2nd-Class) for science and technology by CAS. He also won the
Young Scientist Prize by CAS in 2001, HuGangfu Prize by the Chinese Physical Society in 2011. He is a
fellow of the Optical Society of America. Presently he is the group leader of ultrafast laser and the
director of Joint Laboratory of Advanced Technology in Measurements at Institute of Physics, CAS. He is
also the international advisory member of the journal of Measurement Science and Technology (MST),
member of C2 (Symbol and Constants) sub-committee of international committee of applied physics and
pure physics (IUPAP), committee member of Max-Planck Center for Attosecond Sciences.
TuG2 14:00 Invited
Lattice Stability in Non-equilibrium Warm Dense Matter
Andrew. Ng, Department of Physics & Astronomy, University of British Columbia, Vancouver, British
Columbia, CANADA|
This talk is a brief review of two studies of lattice stability in fs-laser heated Au nanofoils at the Lawrence
Livermore National Laboratory and SLAC National Accelerator Laboratory, using time-resolved Frequency
Domain Interferometry.
29
TuG3 14:20 Invited
CEP-Stabilized Few-Cycle Laser Pulses Based on Supercontinuum from Gas and Solid Media
Kun Zhao,Beijing National Laboratory for Condensed Matter Physics, Institute of Physics, Chinese
Academy of Sciences, Beijing, China
Carrier-envelope phase (CEP) stabilized few-cycle laser pulses have important applications in high-order
harmonic generation (HHG), coherent light synthesis, and isolated attosecond pulse generation in the
extreme-ultraviolet(XUV) band. Up to now, few-cycle laser pulses were generated from gas-filled
hollow-core fibers. However, this scheme suffers a large loss. In this talk, we report our recent progress
on generation of few-cycle laser pulses toward higher energy. With input pulses of 35 fs and 5 mJ at 1kHz,
6.3fs/1.8mJ and 6.7fs/2mJ laser pulses were generated from helium- and neon-filled hollow-core fibers
respectively. To explore for higher pulse energy, we employed a set of thin solid plates to replace the
hollow-core fiber for spectral broadening. Driven by 0.8-mJ, 30-fs laser pulses, 0.7-mJ white light was
obtained through 7 thin silica plates with a thickness of 0.1 mm, corresponding to an efficiency of 87.5%.
Our analysis showed both self-phase modulation and self-steepening played major roles in the
supercontinuum generation. With such an octave spectrum from 450 nm to 980 nm, CEP was measured
and locked directly by an f-2f interferometer. HHG experiments were performed as the CEP was tuned
from 0 to π/2, the cut-off of the observed XUV spectrum changed from continuous to discrete, indicating
that the CEP was successfully locked and controlled.TuG5 15:00
TuG4 14:40 Invited
Relaxation Dynamics after Strong Laser interacting with Dense Hydrogen
Jiayu. Dai, National University of Defense Technology, Hunan, CHINA|
The electron-ion relaxation in warm dense hydrogen is investigated by molecular dynamics (MD)
simulation with Electron Force Field method (eFF), showing extremely low energy exchange rates.
TuG5 15:00 Invited
Brilliant γ-ray flashes and attosecond positron bunches from a nanofiber target driven by ultraintense
lasers
Tongpu. Yu, H. Li, L. Hu, Y. Lu, D. Zou, Y. Yin, F. Shao, National Uni. of Defense Technology, Changsha,
HUNAN, CHINA|
We propose an all-optical scheme for brilliant γ-ray flashes and attosecond positron bunches generation.
The γ-ray flashes are emitted with peak brightness ~1024 photons s-1mm-2mrad-2 and dense
attosecond positrons with flux of 1010 are produced.
30
TuH Terahertz spectroscopy and imaging I
Tuesday, April 24, 2018, TuH 15:40--17:10, Room 1
Xiaoyu Peng, Chongqing Institute of Green and Intelligent Technology, CAS, China, Presider
TuH1 15:40 Keynote
Photoluminescence and Photorflectance Spectroscopy in Infrared of up to Terahertz
Jun. Shao, W. Lu, X. Chen, J. Chu, Shanghai Institute of Technical Physics, Shanghai, SHANGHAI, CHINA|
Recent activities in photoluminescence (PL) and photoreflectance spectroscopies in the Key Laboratory
for Infrared Physics, China, are introduced briefly, with focus on infrared modulated PL method and its
applications to narrow-gap semiconductors.
Jun Shao got his first two university degrees at Nanjing University, and became PhD at Universitaet
Stuttgart. He then devoted to optical spectroscopy, and was selected as Shanghai Subject Chief
Scientist and Existing Talent of the Key Technologies, CAS, and was appointed to Editorial Board of RSI
and AIP in 2010.
TuH2 16:10 Invited
The applications of terahertz parametric sources
Kodo. Kawase, K. Murate, Nagoya University, Chikusa, Nagoya, AIchi, JAPAN|
We report several topics; i) Enhanced tuning range up to 5 THz, ii) 100dB dynamic range THz detection
using near infrared detector, iii) Comparison between is-TPG spectrometer and TDS, iv) THz
Spectroscopic imaging.
TuH3 16:30 Invited
Terahertz time-domain spectroscopy for magnonics and magnetotransport
Zuanming. Jin, X. Liu, S. Zhang, W. Zhao, X. Lin, C. Jin, S. Cao, G. Ma, Shanghai University, Shanghai,
CHINA|Z. Zhang, Fudan University, Shanghai, CHINA|Z. Cheng, University of Wollongong, Wollongong,
New South Wales, AUSTRALIA|J. yao, Tianjin University, Tianjin, Tianjin, CHINA|
Terahertz (THz) time-domain spectroscopy can be used to investigate the spintronic effects, such as
low-energy magnons and magneto transports, in the ultrafast operation regime, sub-picosecond time
scale and/or terahertz frequency range.
TuH4 16:50 Invited
Terahertz spectroscopy under extreme conditions such as high magnetic field, high pressure
Fuhai. Su, Institute of Solid State Physics, Hefei, ANHUI, CHINA|
We studied the Terahertz (THz) spin resonance spectroscopy in magnetic materials under high magnetic
field, and demonstrate the feasibility of THz time-domain spectroscopy up to 20 GPa pressure by
combining diamond anvil cell (DAC).
31
TuI Terahertz science and technology in micro and
nano-structures I Tuesday, April 24, 2018, TuH 15:40--17:10, Room 3
Shengjiang Chang, Nankai University, China, Presider
Jierong Chen, Nankai University, China, Presider
TuI1 15:40 Keynote
Generation and application possibilities of THz pulses with extremely high field strength
Janos. Hebling, Institute of Physics, University of Pecs, Pecs, HUNGARY|
After an overview of high energy THz pulse sources, methods to increase the energy of THz pulses
generated by tilted-pulse-front pumping set-up to few-mJ level, and the application possibilities of these
pulses will be discussed.
János Hebling (M) received the M.S. and Ph.D. degrees in physics from the University of Szeged, Szeged,
Hungary, in 1978 and 1982, respectively. He was with the Max-Planck Institute for Solid State Research,
Stuttgart, Germany, for more than six years and with the Massachusetts Institute of Technology,
Cambridge for two years. He is with the University of Pécs, Pécs, Hungary, where he was the Head of the
Experimental Physics Department from 1999 to 2010 and the Director of the Institute of Physics from
2008 to 2017. Since 2012 he has been the Head of the MTA-PTE High-Field Terahertz Research Group. He
is the author of more than 100 articles and the inventor of 11 patents. His research interests include
ultrafast time-resolved spectroscopy of solids, nonlinear optics, generation and application of terahertz
pulses, and the generation of waveform-controlled attosecond pulses. Prof. Hebling is a Fellow of the
Optical Society of America. He is a topical editor of the Journal of the Optical Society of America B. He is
the recipient of the Pál Selényi, the Széchenyi, and the Ányos Jedlik Awards.
TuI2 16:10 Invited
Semiconductor based THz components
Jinghua. Teng, A*STAR, Singapore, SINGAPORE|
This talk will introduce several of our work on semiconductor based THz components. They include CW
THz emitter using LTGaAs photoconductive antenna, sub-THz detector using GaN 2DEG HEMT, and
tunable THz devices on Si and InSb.
TuI3 16:30 Invited
Active MEMS based THz metamaterials: Memory effects and logical operation
Ranjan. Singh, Nanyang Technological University, Singapore, SINGAPORE|
Microelectromechanical systems provide reconfigurability to THz metamaterials and have become an
important area of photonic research. Here, I will present three-dimensional symmetry broken Fano
resonators using MEMs cantilever that enable memory effects and logical operations.
TuI4 16:50 Invited
Terahertz surface plasmons with metasurface
Jiaguang. Han, Tianjin University, Tianjin, TianJin, CHINA|
Surface plasmon polaritons (SPPs) promise versatile potential applications in many aspects and thus
have been a subject of enormous interest. However, in the terahertz regime, due to perfect conductivity
of most metals, it is hard to realize a strong confinement of SPPs although a propagation loss could be
sufficiently low. Here we introduce the recent work from terahertz surface waves to spoof SPPs based on
metasurfaces.
32
TuJ High-field physics and attosecond science II Tuesday, April 24, 2018, TuH 15:40--17:10, Room 2
Xiaojun Liu, Wuhan Institute of Physics and Mathematics, China, Presider
TuJ1 15:40 Keynote
Nonadiabatic effect of strong-field tunneling ionization
Yunquan. Liu, School of Physics, Beijing, BEIJING, CHINA|
We will present the systematic study on nonadiabatic effect of strong-field tunneling ionization.
Prof. Yunquan Liu obtained the PhD degree from the Institute of Physics, Chinese Academy of Sciences in
2006. Then he moved to Max-Planck-Institute for Nuclear Physics for the postdoc research in the period
of 2006-2009. He joined Peking Unviersity as “Bairen Professor”. He was awarded “Distinguished Young
Scientist” by National Science Foundation of China in 2011, “The Rao Yu-tai” by Chinese Optical Society
(COS) in 2010, “Wang Xuan” for young Scientist in 2012 and “Wang Da-Heng” awards in 2013. In 2014,
he was awarded “Cheung-Kong” Professor of Ministry of Education and “Young innovation talents of
Science and technology” of Ministry of Science and Technology. He has published over 100 papers on
international journals in the field of ultrafast physics.
TuJ2 16:10 Invited
Ultrafast dynamics of electrons in strong-field ionization of molecules
Jian. Wu, East China Normal University, Shanghai, CHINA|
We demonstrate experimental observation of a Freeman resonance time delay of 140 ± 40 attoseconds
between the photoelectrons emitted via different Rydberg states of Argon, the control of the
rescattering of the freed electron by manipulating the waveform of the laser field, the photon-energy
spaced above threshold dissociation spectrum and the dissociative frustrated double ionization of
hydrogen molecules.
TuJ3 16:30 Invited
Few-photon strong-field ionization
Ulf. Saalmann, Q. Ning, M. Baghery, S. Giri, J. Rost, MPI fur Physik komplexer Systeme, Dresden,
GERMANY|
Ionization with strong and short pulses in the ultraviolet region offers more than just single-photon
absorption. We review recently discovered physical phenomena in this new regime of light-matter
interaction.
TuJ4 16:50 Invited
Electron correlation from strong field ionization of noble gas atoms subject to intense laser field
Wei. Quan, Y. Wang, X. Lai, X. Liu, WIPM, CAS, Wuhan, HUBEI, CHINA|X. Hao, W. Li, Shanxi University,
Taiyuan, CHINA|W. Becker, Max Born Institut, Berlin, GERMANY|Y. Wu, J. Wang, J. Chen, Institute of
Applied Physics and Computational Mathematics, Beijing, CHINA|
Electron-electron correlation is revealed in nonsequential double ionization (NSDI) of noble gas atoms
subject to intense laser fields experimentally and theoretically. A novel laser-induced inelastic diffraction
scheme based on NSDI is proposed.
33
TuK Poster session I (ultrafast phenomena) Tuesday, April 24, 2018, TuK 17:10--18:30, Room 2
TuK1
Dissociative double ionization of Ar dimer in femtosecond laser fields of different light intensity
P. Song, C. Meng, X. Wang, W. Dong, J. Liu, L. Liu, Z. Lu, D. Zhang, Z. Zhao, J. Yuan, National University of
Defense Technolog, Changsha, HUNAN, CHINA|
We experimentally studied the dissociative double ionization of Ar2 in femtosecond laser fields of
different light intensity. The experimental results show a significant regulatory effect of light intensity to
dissociative double ionization of Ar2.
TuK2
Single-shot imaging of molecular structure using two-color orthogonally polarized fields
C. Zhai, X. Zhang, X. Zhu, L. He, Y. Zhang, B. Wang, Q. Zhang, P. Lan, P. Lu, Wuhan National Laboratory for
Optoelectronics and School of Physics, Huazhong Univ of Science and Technology, Wuhan 430074,
CHINA|P. Lu, Laboratory of Optical Information Technology, Wuhan Institute of Technology, Wuhan
430205, CHINA|
We report a single-shot molecular orbital tomography scheme with orthogonal two-color(OTC) fields.
Using OTC fields, the two-dimensional motion of electron is controlled and the highest occupied
molecular orbital of N2 is reconstructed in experiment.
TuK3
Few cycle pulses IR laser system based on a bandwidth-optimized high energy Yb-doped fiber laser:
Application to XUV generation
M. Natile, A.I. Gonzalez, Amplitude Technologies, Lisses, FRANCE|L. Lavenu, M. Natile, M. Hanna, P.
Georges, Laboratoire Charles Fabry, Institut d'Optique Graduate School, CNRS, Université Paris-Saclay,
Palaisceau, FRANCE|L. Lavenu, F. Guichard, Y. Zaouter, E. Mottay, Amplitude Systèmes, Pessac, FRANCE|T.
Ruchon, CEA LIDyL, CEA, CNRS, Université Paris-Saclay, Gif-sur-Yvette, FRANCE|
We report on an efficient few-cycle laser based on a high-energy Yb-doped fiber amplifier, delivering 14
fs, 120 µJ pulses at 200kHz. We drive HHG achieving a cutoff of 140eV with photon flux of
1012photons/s/eV.
TuK4
Generation of intense few-cycle blue femtosecond laser pulses
X. Fan, X. Wang, D. Zhang, J. Zeng, Department of Physics, National University of Defense Technology,
Changsha, HUNAN, CHINA|
We report second harmonic generation with BBO crystal from intense few-cycle infrared femtosecond
laser pulses, we managed to get broadband phase-matching with 14.2% conversion efficiency, and the
result ultraviolet spectra supports 7.0 fs pulses.
TuK5
Research on The Carrier Density Threshold in The High-gain GaAs Photoconductive Semiconductor
Switch at 4μJ Excitation
S. wang, W. Shi, C. Dong, L. Yang, D. Duan, Xi’an University of Technology, Xi’an, SHaanxi, CHINA|
The relationship between the carrier density threshold and the electric field is deduced, and a good
correspondence is established between the theory and experimental results.
TuK6
Low repetition rate tunable femtosecond pulses generated from a fiber optical parametric oscillator
K. Yang, H. Li, P. Ye, Q. Hao, H. Zeng, Univ of Shanghai Science & Technology, Shanghai,Yangpu, SHanghai,
CHINA|
34
We demonstrated generation of 800-kHz tunable femtosecond pulses from 970 to 1020 nm via a fiber
optical parametric oscillator. The generated pulses could be used as a simple and flexible light source for
biomedical applications.
TuK7
Study of Correlated Excitation Dynamics of One-dimensional Model Helium
W. Dong, L. Liu, J. Liu, Y. Huang, J. Zhao, Z. Zhao, National University of Defense Technology, Changsha,
HUNAN, CHINA|
We study the ionic excitation of helium system in strong laser fields. The simulation results show that the
interplay of the electron-electron correlation, singly and doubly ionization and rescattering dynamics.
TuK8
Femtosecond Fiber Laser Developed For Real-time Terahertz Spectrometer
S. Cui, J. Chen, Y. Yuan, F. Sun, Huazhong Institute of Electro-Optics, Wuhan, HUBEI, CHINA|Y. Yuan, Hubei
Jiuzhiyang Infrared System Co., Ltd, Wuhan, CHINA|
A femtosecond fiber laser, which employs an environmentally stable all-PM seed and two fiber chirped
pulse amplifiers, has been successfully developed and integrated in a 0.1–7 THz broadband real-time
terahertz spectrometer.
TuK9
Probing the charge carrier dynamics and photoconductivity of few-layer SnS2 by optical pump-THz
probe spectroscopy
W. Zhang, Q. Lu, S. Zhang, W. Zhao, L. Lv, X. Lin, Z. Jin, G. Ma, Shanghai University, Shanghai, CHINA|J.
yao, Tianjin University, Tianjin, CHINA|
By using optical-pump terahertz-probe spectroscopy, we investigated the photo-excited THz conductivity
dynamics of CVD grown SnS2 laminate, which is a semiconducting 2D material with earth abundant,
nontoxic constituent elements.
TuK10
Positron generation via ultra-intense laser irradiating a tapered hollow foam-like target
J. Liu, Y. Ma, T. Yu, College of Liberal Arts and Sciences, National University of Defense Technology,
Changsha, Hunan, CHINA|J. Liu, Wuhan Electronic Information Institute, Wuhan, Hubei, CHINA|
An improved scheme for high-flux, low-divergence and high-energy positrons generation is proposed.
With a thick extra layer and a hollow cone, positron generation is enhanced, and the beam collimation
and energy are well kept.
TuK11
THz spectroscopy of terbium–scandium–aluminum garnet crystal and its application to ultrafast
all-optical switching
J. Li, J. Zhang, X. Lin, Z. Jin, G. Ma, Shanghai University, Shanghai, CHINA|X. Chen, N. Zhuang, Fuzhou
University, Fuzhou, CHINA|Z. Zhang, Fudan University, Shanghai, CHINA|A. Wu, Shanghai Institute of
Ceramics, Chinese Academy of Science, Shanghai, CHINA|
We have used time-domain THz spectroscopy to study the electronic transition in the ground multiplet
of TSAG crystal. In addition, by the time-resolved probe measurement to operate an all-optical
magneto-optical switching in TSAG crystal.
TuK12
Investigation on the dispersion compensation of femtosecond optical vortex generated by hologram
grating
Y. tu, Z. wang, D. Zhang, Z. Zhao, National University of Defense Technolog, CHANGSHA, HUNAN, CHINA|
This paper presents a new method of dispersion compensation based on holographic grating plate
combined with lens imaging system. In the experiment, we have produced a femtosecond vortex beam
35
with no mode distortion on the basis of the new method.
TuK13
Non-adiabatic imprints on the lateral electron-momentum distribution of the low-energy structure in
mid-infrared above-threshold ionization
Z. Lin, L. Baoqing, Huaqiao University, XiaMen, Fujian, CHINA|
We demonstrate the measured peculiar wavelength-dependent angular distributions (ADs) of the
low-energy electrons are related to the non-adiabatic effects on the initial lateral electron-momentum
distribution by using an improved semiclassical model.
36
TuK Poster session I (THz waves) Tuesday, April 24, 2018, TuK 17:10--18:30, Room 3
TuK14
Highly Efficient Terahertz Generation in a Circularly Polarized Two-Color Laser Field
C. Meng, Xi'an Research Institute of High-tech, Xi'an, CHINA|Y. Tu, Q. Guo, Y. Huang, Z. Lu, X. Wang, C.
Meng, D. Zhang, Z. Zhao, J. Yuan, National University of Defense Technology, Changsha, CHINA|J. Yuan,
Graduate School of China Academic of Engineering Physics, Beijing, CHINA|
We experimentally demonstrate that the optical-to-THz conversion efficiency in circularly-polarized
two-color laser fields is higher than that in linearly-polarized two-color system.
TuK15
Broadband Terahertz Quantum Cascade Laser with Radio Frequency Modulation
W. Wan, H. Li, J. Cao, Shanghai Institute of Microsystem and Information Technology, Chinese Academy of
Sciences, Shanghai, CHINA|
We present broadband quantum cascade lasers emitting around 4.3 THz. A low beam divergence of 3° is
achieved by using Silicon lens, and homogenous spectral broadening over 300 GHz is obtained with radio
frequency modulation.
TuK16
Research on Envelope Correction of Precession Cone Targets in the Terahertz Band
Q. Yang, H. Wang, B. Deng, Y. Qin, H. Zhang, National University of Defense Technolog, Changsha, Hunan,
CHINA|
An envelope correction method based on multi-layer perceptron for ballistic missile targets in the
terahertz region was proposed. Then a 330GHz imaging radar was introduced and experiment on a
precession cone model was carried out.
TuK17
Preliminary measurement of the characters of CAEP THz free electron laser
D. Wu, P. Li, P. Zhang, M. Li, Institute of Applied Electronics, Mian, SiChuan, CHINA|
This paper presents the preliminary measurement of the CAEP THz free electron laser, including
macro-pulse power, duty cycle, beam transvers profile, beam length, etc.
TuK18
Ultrafast THz probe of photoexcited free charge carriers in CH3NH3PbI3 and
CH3NH3PbI3/Spiro-OMeTAD perovskites
W. Zhao, H. Yan, X. Lin, Z. Jin, G. Ma, Shanghai University, Shanghai, CHINA|Z. Ku, Wuhan University of
Technology, Wuhan, CHINA|
We have used transient terahertz (THz) photoconductivity measurements to demonstrate that upon
optical excitation of CH3NH3PbI3 perovskite, the hole transfers from CH3NH3PbI3 into organic
hole-transporting material (HTM) Spiro-OMeTAD.
TuK19
Phase Transition from CsPbBr3 into CsPb2Br5 during Size Increasing of Perovskite Nanocrystals
Observed by Terahertz Time-Domain Spectroscopy
H. Shi, X. Zhang, X. Sun, X. Zhang, South University Of Science And Technolo, Shenzhen, GUangDong,
CHINA|
The phase transition of perovskite nanocrystals during nanocubes-nanoplates size increasing is
evidenced by the different terahertz transmission results. This help to study the application of perovskite
as terahertz functional devices.
TuK20
37
Generation and Characterization of a THz Bottle Beam
H. Li, X. Wang, W. Sun, S. Feng, P. Han, J. Ye, Y. Zhang, Capital Normal University, Beijing, BEIJING,
CHINA|S. Wang, Shandong Normal University, Jinan, CHILE|
Terahertz (THz) bottle beams are generated by using a silicon lens and a Teflon axicon. The evolutions of
the transverse (Ex) and longitudinal (Ez) electric fields are coherently measured and simulated of the
phenomena.
TuK21
High power 4.4 THz quantum cascade lasers and its application in higher resolution imaging
T. Jiang, C. Shen, Z. Zhan, R. Zou, X. Wang, W. Li, Q. Deng, W. Wu, Research Center of Laser Fusion CAEP,
MianYang, SICHUAN, CHINA|
We present our research on the fabrication of high power THz QCLs with frequency at 4.4 THz and its
application on the holographic imaging. With application of the THz QCL, the lateral resolution in
holographic imaging system can reach 80μm.
TuK22
The correction of THz-time domain reflection spectroscopy of SrTiO3
Q. Guo, D. Zhang, J. Yuan, National University of Defense Technology, Changsha, Hunan, CHINA|J. Yuan,
Graduate School of China Academic of Engineering Physics, Beijing, CHINA|
The experimental results of SrTiO3 from 0.3THz to 6THz shows that an analytic continuation of the
complex reflection can reduce the impact of limited spectra so that a more accurate correction can be
acquired.
TuK23
The influence of humidity and PM2.5 on the communication performance of terahertz system
Z. Xiong, J. He, B. Zhang, B. Su, C. Zhang, Department of Physics, Capital Normal University, Key
Laboratory of Terahertz Optoelectronics, Ministry of Education; Beijing Key Laboratory for Terahertz
Spectroscopy and Imaging; Beijing Advanced Innovation Center for Imaging Technology, Beijing, CHINA|
In this paper, we explore the influence of humidity and PM2.5 on communication quality in terahertz
communication system, and provide theoretical reference for selecting proper channel parameters for
terahertz wireless communication.
TuK24
Terahertz Spin Emitter
D. Kong, T. Nie, C. Ruan, W. Zhao, X. Wu, School of Electronic and Information Engineering, Beihang
University, Beijing, CHINA|B. Wang, L. Wang, Beijing National Laboratory for Condensed Matter Physics,
Institute of Physics,Chinese Academy of Sciences, Beijing, CHINA|B. Wang, School of Physical Sciences,
University of Chinese Academy of Sciences, Beijing, CHINA|T. Nie, W. Zhao, Fert Beijing Institute, BDBC,
Beihang University, Beijing, CHINA|
We demonstrate efficient and broadband terahertz generation from magnetic nanofilms pumped by
femtosecond laser pulses, which can be used as sources for spectroscopy and has the capability for
strong-field terahertz induced nonlinear investigations.
TuK25
An Ultrasensitive Dual-band Terahertz Metamaterial Microfluidic Sensor
F. Feng Luo, University of Electronic Science and Tec, Chengdu, SiChuan, CHINA|
We present an novel high sensitivity dual-band terahertz metamaterial microfluidic sensor,which shows
a nearly perfect absorption and perfect spatial overlap between the analytes and the electric field,and
exhibits promising application in biosensing
TuK26
Plasmonic Analog of Electromagnetically Induced Transparency Based on Terahertz Stereo
38
Metamaterials
L. Dachuan, The 53rd Research Institute of CETC, Tianjin, TianJin, CHINA|Z. Huifang, J. Gu, Y. Li, Z. Tian, O.
Chunmei, J. Han, W. Zhang, Tianjin University, Tianjin, CHINA|
A novel THz stereo PIT metamaterial
TuK27
Influence of the bandwidth of two incident pulses on two-dimensional terahertz spectroscopy
F. Xiang, K. Wang, Z. Yang, J. Liu, Wuhan National Lab. for Optoelectronics, Wuhan, HUBEI, CHINA|
The influence of the bandwidth of two incident terahertz pulses on two-dimensional terahertz
spectroscopy has been studied theoretically via a classical method. This study is promising for guiding
experiments using different terahertz sources.
TuK28
Terahertz biosensing metasurface for virus detection based on spoof surface plasmon polaritons
D. Cheng, G. Liu, Y. Luo, B. Zhang, Y. Chen, Y. Lin, Y. Wang, Z. Dang, University of Electronic Science and
Technology of China, ChengDu, CHINA|G. Shu, Shenzhen University, ShenZhen, CHINA|
Planar Jerusalem cross metasurface for different virus detection based on spoof surface plasmon
polaritons (SSPPs) in Terahertz (THz) band is investigated, which shows great significance on the
contagious and time-sensitive target virus.
TuK29
Active Modulation of Coupled-Cavity Terahertz Quantum Cascade Lasers for Sideband generation
Z. Li, H. Li, W. Wan, K. Zhou, T. Zhou, J. Cao, Chinese Academy of Sciences, Key Laboratory of Terahertz
Solid-State Technology, Shanghai, CHINA|Z. Li, H. Li, W. Wan, K. Zhou, T. Zhou, J. Cao, Chinese Academy of
Sciences, Shanghai Institute of Microsystem and Information Technology, Shanghai, CHINA|
We experimentally demonstrate that the coupled-cavity terahertz quantum cascade lasers can be
actively modulated to generate sidebands under injecting frequencies that are equal to the harmonics of
the difference frequency between transverse modes.
TuK30
Polarization splitting based on the orthogonally exotic I-shaped
H. Zeng, University of Electronic Science and Technology, Chengdu, CHINA|
We designed an orthogonally exotic I-shaped metamaterial that controls the reflection phase of different
polarizations independently. Greatly improve the ability of phase adjustment to different polarized
beams.
TuK31
Tunable Terahertz Perfect Absorber Based on Spatially Separated Double-layer Graphene
R. Yang, X. Wei, NUDT, Changsha, Hunan, CHINA|
We theoretically proposed a perfect absorber operating in terahertz wavelength based on spatially
separated double-layer graphene with the upper layer of graphene patterned with periodical holes,
which facilitates active tuning plasmonic devices.
TuK32
New Trigger Signal Triggering Method Based on Asynchronous Scanning System
X.Y. wu, B. Su, X. Wu, J. He, S. Zhang, C. Zhang, Capital Normal University, Beijing, BEIJING, CHINA|
Asynchronous high-speed scanning system is a new technology for terahertz time-domain spectroscopy
system. Compared with the conventional that based on mechanical delay lines, it offers the advantages
of high spectral resolution and fast scanning.
TuK33
Active bidirectional control hybrid based on organic materials for terahertz waves
W. wang, Capital Normal University, Beijing, CHINA|
39
With optical and electrical excitations, we experimentally demonstrated active bidirectional modulation
for terahertz consisting of MEH-PPV/Pedot:Pss/Si/Pedot:Pss structure and obtained bidirectional
transmission modulation from -54% to 60%.
TuK34
An active optically controlled broadband terahertz modulator based on Fe3O4 nano-particles
L. Xiong, B. Zhang, H. Ji, W. Wang, X. Liu, J.L. Shen, Capital Normal University, Beijing, BeiJIng, CHINA|
We report an active easily fabricated broadband terahertz modulator based on Fe3O4 nano-particles/Si
structure,for which as high as 92% modulation depth was achieved at an external excitation laser of 3.6
W/cm2.
TuK35
Detecting Terahertz Continuous Wave Using Weakly Ionized Plasma
L. Hou, W. Shi, Xi'an University of Technology, Xian, SHAANXI, CHINA|
In this paper, we designed a THz continuous wave detector using weakly ionized plasma generated by
discharging inert gas. Some applications of the weakly ionized plasma detector in THz wave detection
and imaging were demonstrated.
TuK36
High-resolution CW Terahertz Spectroscopy of Nanogap Terahertz Metamaterials
M. Xiao, D. KONG, K. Chen, C. Ruan, X. Wu, School of Electronic and Information Engineering, Beihang
University, Beijing, CHINA|B. Quan, Beijing National Laboratory for Condensed Matter Physics, Institute
of Physics, Chinese Academy of Sciences, Beijing, CHINA|
High-resolution CW terahertz spectroscopy of nanogap metamaterials with different polarization
excitation is characterized.The combination of the results from two orthogonal linear polarizations is
proportional to that from the circular polarization.
TuK37
Electrically tuned transmission properties of cutwire-BTO-Si hybrid structure in terahertz range
S. Zhou, J. Ji, Y. Tian, F. Ling, W. Yu, Huazhong Univ of Science and Technology, Wuhan, Hubei, CHINA|
Transmission and dielectric properties of the cutwire-BTO-Si hybrid structure were characterized. There
is a dip in the transmission spectra due to LC resonance. The electric field could tune the transmission
and dielectric property effectively.
TuK38
Energy relaxation in scattering-assisted terahertz quantum cascade lasers
F. Wang, SIMIT, CAS, Shanghai, ShangHai, CHINA|
The optoelectronic system is simulated self-adaptively. Calculated electronic temperatures and energy
relaxation times in the lasing-establishment process from unsaturated to saturated states, are in good
agreement with experimental results.
TuK39
All-optical Terahertz Modulation Based on WSe2-silicon Hybrid Structures
C. XIA, School of Automation Science and Electrical Engineering, Beihang University, Beijing, CHINA|Z.
Fang, X. Wu, School of Electronic and Information Engineering, Beihang University, Beijing, CHINA|Y.
Huang, B. Wang, L. Wang, Beijing National Laboratory for Condensed Matter Physics, Institute of Physics,
Chinese Academy of Sciences, Beijing, CHINA|B. Wang, School of Physical Sciences, University of Chinese
Academy of Sciences, Beijing, CHINA|Z. Li, Max-Planck Institute for the Structure and Dynamics of Matter,
Hamburg, GERMANY|
We experimentally demonstrate an all-optical modulation for terahertz waves based on an atomic
monolayer WSe2-silicon hybrid structure. Compared with the modulation from naked silicon substrate,
the modulation depth is scaled up by ~40%.
40
TuK40
Analysis of Terahertz Transmission in Aging of Natural Rubber Products
X. zhang, J. Gao, Qilu University of Technology (Shandong Academy of Sciences), JINAN, Shandong,
CHINA|
Natural rubber product is aged for about 1000 hours in a hot oxygen environment at 100°C. The
attenuation characteristics of 0.325-0.5 THz are tracked every 24 hours.
TuK41
Preparation of VO2 thin films by sol - gel method and its terahertz modulation characteristics
Z.X. Shi, H. Wang, J. He, B. Su, C. Zhang, Capital Normal University, Beijing, BEIJING, CHINA|
VO2 thin films were prepared on silica wafer by sol-gel method and spin coating technology. The
insulator metal phase transformation characteristics of thin films were analyzed by terahertz
time-domain spectroscopy, showing a good modulation effect.
TuK42
Generation of Terahertz Hollow-Gaussian Beams from Two-Color Vortex Laser-Induced Gas-Plasma
H. Wang, E. Wu, Z. Wang, Tongji University, Shanghai, CHINA|H. Wang, Y. Bai, E. Wu, P. Liu, C. Liu,
Shanghai Inst of Optics & Fine Mechanics, Shanghai, CHINA|
A method for generating terahertz (THz) hollow-Gaussian beam without orbital angular monument
(OAM) from two-color vortex laser-induced gas-plasma is proposed and theoretically confirmed.
TuK43
Active Fano-resonant metasurface device based on graphene monolayer in the terahertz regime
Q. Li, S. Wang, T. Xu, School of Electronic Engineering, Tianjin University of Technology and Education,
Tianjin, Tianjin, CHINA|Q. Li, S. Wang, National-Local Joint Engineering Laboratory of Intelligent
Manufacturing Oriented Automobile Die & Mould, Tianjin University of Technology and Education,
Tianjin, Tianjin, CHINA|
We demonstrate an active Fano-resonant metasurface device that consists of a monolayer graphene and
symmetry broken Fano resonators. A large modulation up to 89% was experimentally observed by
simultaneous CW optical pump and electrical gating.
TuK44
Cocrystallization within Gamma-aminobutyric Acid and Benzoic Acid Based on Terahertz and Raman
Spectroscopy
X. Huang, Q. Zhang, Q. Cai, Y. DU, China Jiliang University, Hangzhou, ZHEJIANG, CHINA|
Vibrational spectroscopic methods, including terahertz and Raman spectroscopy, were utilized for the
characterization and analysis of gamma-aminobutyric acid (GABA), benzoic acid (BA), and the
corresponding GABA-BA cocrystal formation.
TuK45
A SI-GaAs photoconductive array antenna based on self-focusing microlens
C. Dong, W. Shi, S. wang, L. Yang, L. Wang, Xi'an University of Technology, Xi'an, SHaanxi, CHINA|
The GaAs photoconductive antenna (GaAs PDA), that is still a problem to improving the radiation power
of GaAs PDA. In order to improve the radiation power, we have studied the unit antenna and GaAs PDA
array, adapted to the terahertz research needs.
TuK46
Investigation of Electrical and Optoelectronic Properties of CdSxSe1-x nanobelts by using THz
spectroscopy
H. Liu, L. Ke, Institute of Materials Research& Engineering, Singapore, SINGAPORE|
In this work, composition-dependent electron transport, ultra-high photoconductivity and carrier
dynamics of CdSxSe1-x nanobelts have been studied by using optical-pump THz-probe spectroscopy.
41
TuK47
Terahertz dielectric response and optical conductivity of layered MoS2
H. Li, X. Zhang, Southern Univ of Science & Technology, Shenzhen, GUANGDONG, CHINA|H. Li, Z. Tang,
IAPME, UM, Macau, MACAO|
Both THz-TDS of multilayer and monolayer MoS2 are studied. A series of frequency dependent
parameters are calculated in the frequency range of 0.2 to 2.25 THz. The optical conductivity are
analyzed by Drude model.
TuK48
A 300GHZ Standard Waveguide Loaded Artificial Microstructure Phase Shifter
Shi Jinxin1, 1. Terahertz Research Centre, School of Phys., Chengdu, SICHUAN, China.
This paper presents a terahertz(THz)-wave 280GHz-340GHz phase shifter. Get the maximum phase shift
exceeds 100 °, the phase shift accuracy is less than 10 °, the average insertion loss is less than 1.3dB.
TuK49
Terahertz frequency-tunable device based on interference by photo-excitation of polymer/silicon
hybrid structure
D. Liu, B. Zhang, W. Wang, H. Ji, G. Wang, J.L. Shen, Capital Normal University, Beijing, CHINA|
When the terahertz beam passes through the sample edge, equally-spaced interference fringes are
obtained in the frequency domain, and the interference fringes can be varied using an external
continuous wave laser.
42
WA Plenary session II
Wednesday, April 25, 2018, WA 8:30--10:00, Room 1
Peiheng Wu, Nanjing University, China, Presider
WA1 8:30 Plenary
Progress in ultrafast terahertz scanning tunneling microscopy
Frank. Hegmann, University of Alberta, Edmonton, Alberta, CANADA|
The ability to directly probe ultrafast phenomena on the nanoscale is essential to our understanding of
excitation dynamics on surfaces and in nanomaterials. Recently, a new ultrafast scanning tunneling
microscope (STM) technique that couples terahertz (THz) pulses to the scanning probe tip of an STM was
demonstrated (THz-STM), showing photoexcitation dynamics of a single InAs nanodot with simultaneous
0.5 ps time resolution and 2 nm spatial resolution under ambient conditions. Operation of THz-STM in
ultrahigh vacuum now makes it possible to spatially-resolve subpicosecond dynamics of single molecules
and silicon surfaces with atomic precision. This talk will discuss how THz-STM works, recent progress,
and how THz-STM can provide new insight into ultrafast dynamics on the atomic scale, which is essential
for the development of novel silicon nanoelectronics and molecular-scale devices operating at terahertz
frequencies.
WA2 9:15 Plenary
High energy and high efficiency chirped pulse amplifiers in 10 PW laser
Xiaoyan. Liang, Z. Gan, W. Li, L. Yu, Y. Liu, C. Wang, Y. Hang, Y. Leng, R. Li, Z. Xu, Shanghai Inst of Optics &
Fine Mechanics, Shanghai, Shanghai, CHINA|
A high energy and efficiency amplifier in SULF laser was demonstrated with output energy of 339J, which
contained a Ti:Sapphire crystal with diameter of 235mm. After compression, the peak power of 10.3 PW
was achieved.
43
WB Terahertz application Wednesday, April 25, 2018, WB 10:20--12:00, Room 1
Hongqiang Wang, National University of Defense Technology, China, Presider
WB1 10:20 Keynote
Development of Superconducting Mixers and Detectors for the DATE5 Telescope
Shengcai. Shi, Purple Mountain Observatory, Nanjing, JIangSu, CHINA|S. Shi, Key Lab of Radio Astronomy,
Nanjing, China, CHINA|
China is planning to construct a 5-m THz telescope (DATE5) at Dome A, Antarctic. This talk will introduce
our FTS atmospheric measurement results from Dome A, and the latest development of superconducting
mixers and detectors for the DATE5.
S. Shi received his B.S. degree from Southeast University, China, in 1985, M.S. degree from Graduate
School of Chinese Academy of Sciences, China, in 1988, Ph.D. degree in radio astronomy from the
Graduate University for Advanced Studies, Japan, in 1996. His research interests include physics of
superconducting devices, THz mixers and detectors, and THz applications.
WB2 10:50 Invited
Liquid-Crystal-Enabled Magnetically and Electrically Tunable Achromatic Quarter-Wave Plates
Ciling. Pan, National Tsing Hua University, Hsinchu City, TAIWAN|
We review progress in THz achromatic quarter-wave plates that can be tuned using magnetically or
electrically tuned birefringence of liquid crystals.
WB3 11:10 Invited
Synthesis of the Scattering Features of THz Waves via Metasurfaces
Qiang. Cheng, J. Zhao, C. zhang, Southeast University, Nanjing, CHINA|
Here we will report some recent progress in controlling the THz scattering features via metasurfaces,
which is beneficial for future applications of novel THz antennas, imaging and radar systems.
WB4 11:30 Contributed
Vehicle-borne THz-SAR Imaging Based on Azimuth Doppler Rate Estimation
Q. Liu, H. Wang, Bin. Deng, Y. Zhang, Q. Yang, J. Gao, H. Zhang, National University of Defense Technolog,
Changsha, HUNAN, CHINA|
An imaging method based on the azimuth Doppler rate estimation of the vehicle-borne THz-SAR is
proposed. The method can avoid the distance error interference efficiently and obtain an imaging result
with a higher azimuth resolution.
WB5 11:45 Contributed
THz Hyperspectral Images Analyzed by Multivariate Statistical Methods
Pu. Zou, O. Peters, C. Gleichweit, R. Holzwarth, Menlo Systems GmbH, Martinsried, GERMANY|H.
Lohninger, Institute of Chemical Technologies and Analytics, Vienna University of Technology, Vienna,
AUSTRIA|
Images recorded using Terahertz Time-Domain Spectroscopy contain huge amounts of data, of which
only a part may contain chemical and structural information. Using powerful hyperspectral image
analysis, we extract both information efficiently.
44
WC Terahertz science and technology in micro and
nano-structures II Wednesday, April 25, 2018, WC 10:20--12:00, Room 3
Guohong Ma, Shanghai University, China, Presider
WC1 10:20 Keynote
Single-Cavity, Dual-Comb Ultrafast Fiber Lasers and Their Terahertz Dual-Comb Metrology Applications
X. Zhao, G. Hu, Zheng. Zheng, School of Electronic and Information Engineering, Beihang University,
Beijing, BEIJING, CHINA|Z. Zheng, Beijing Advanced Innovation Center for Big Date-based Precision
Medicine, Beijing, CHINA|T. Yasui, Graduate School of Technology, Industrial and Social Sciences,
Tokushima University, Tokushima, JAPAN|T. Yasui, JST, ERATO, MINOSHIMA Intelligent Optical Synthesizer
Project, Tokushima, JAPAN|
Dual-comb mode-locked fiber lasers emitting asynchronous pulse trains have emerged as alternative,
low-complexity dual-comb sources. We demonstrate that terahertz time-domain spectroscopy and
frequency characterization could benefit from such lasers.
Prof. Zheng Zheng received his Bachelor's degree from Tsinghua University and MSEE and Ph.D. degrees
from Purdue University. He was an MTS with Lucent Technologies, NJ before he joined Beihang University
in December 2003. He is a Fellow of Chinese Institute of Electronics, and IEEE and OSA member.
WC2 10:50 Invited
Inversionless Terahertz Gain in Semiconductor Superlattices up to Room Temperature and above
Takeya. Unuma, A. Matsuda, A. Naka, Nagaoka University of Technology, Nagaoka, Niigata, JAPAN|K.
Hirakawa, University of Tokyo, Meguro-ku, Tokyo, JAPAN|
We investigate temperature-dependent complex conductivity spectra of GaAs-based superlattices by
terahertz emission spectroscopy under bias electric field. We provide direct evidence for inversionless
terahertz gain up to room temperature and above.
WC3 11:10 Invited
Nonlocal transistor based on a EuO-graphene/superconductor hybrid structure
Chao. Zhang, University of Wollongong, Wollongong, New South Wales, AUSTRALIA|Y. Ang, L. Ang,
Singapore University of Technology and Design, Singapore, SINGAPORE|Z. Ma, Peking University, Beijing,
CHINA|
We show that pure crossed Andreev reflection can be generated in an N/S/N device. This allows the
device acts as a highly tunable transistor that operates purely in the non-local transport regime.
WC4 11:30 Contributed
THz Radiation via Inverse Rashba-Edelstein effect
Jingbo. Qi, Univ of Electronic Sci & Tech of China, Chengdu, SICHUAN, CHINA|
Using the inverse Rashba-Edelstein effect, we demonstrate a novel type of strong broadband THz emitter
composed of ferromagnetic metallic heterostructures. The emitted THz wave has a bandwidth
dominating ~0.1-5 THz.
WC5 11:45 Contributed
Propagation of the Blackbody Radiation in a Periodic Metamaterial
Peter. Lerner, Wenzhou Kean University, Wenzhou, ZHEJIANG, CHINA|P.B. Lerner, SciTech, LLC, State
College, Pennsylvania, UNITED STATES|
Partially coherent beam passing through a periodic lattice retains its coherence on propagation at the
Talbot distance. Potentially infinite enhancement of spatial coherence of a blackbody radiation by a
metamaterial can be used for THZ detection.
45
WD High-field physics and attosecond science III Wednesday, April 25, 2018, WD 10:20--12:00, Room 2
Liangyou Peng, Peking University, China, Presider
WD1 10:20 Keynote
An anatomy of strong field ionization induced air lasing
J. Yao, W. Chu, Z. Liu, J. Chen, B. Xu, Ya. Cheng, State Key Laboratory of High Field Laser Physics, Shanghai
Institute of Optics and Fine Mechanics, Chinese Academy of Sciences, Shanghai, CHINA|Y. Cheng, School
of Physics, Chinese Academy of Sciences, Beijing, CHINA|
Tunnel ionization of nitrogen molecules with mid- and near-infrared intense laser fields can initiate lasing
actions at various wavelengths. The physical mechanisms behind the observation will be discussed in this
talk.
Ya Cheng is a professor of the Shanghai Institute of Optics and Fine Mechanics, Chinese Academy of
Sciences (CAS). He is also a professor of East China Normal University (ECNU), and currently serves as the
Dean of the School of Physics and Materials Science, ECNU. He received a BS degree from Fudan
University in 1993 and a PhD degree from the Shanghai Institute of Optics and Fine Mechanics, CAS in
1998. His research focuses on ultrafast nonlinear optics and strong field laser physics. He has
co-authored more than 200 papers in peer reviewed journals, which have been cited more than 5000
times. His current H-index reaches 39 based on Web of Science. He is a Fellow of the Institute of Physics,
UK.
WD2 10:50 Invited
Neutral excitation of atoms and molecules induced by ultrafast strong laser fields
Haifeng. Xu, Jilin University, Changchun, JILIN, CHINA|
We perform joint experimental and theoretical studies on neutral Rydberg state excitation (RSE) induced
by 50-fs 800-nm strong laser fields, for both atoms and molecules. Possible mechanism and
molecular-structure effect of RSE are discussed
WD3 11:10 Invited
High-harmonic spectroscopy of electron-hole dynamics induced by strong-field ionization
Jing. Zhao, J. Yuan, Z. Zhao, National University of Defense Technolog, Changsha, HUNAN, CHINA|
We propose an IR-pump-XUV-probe scheme to investigate multi-electron-hole coherence. Using the
laser-induced ionization as a gate for XUV excitation of core electrons provides us the opportunity to
probe both the core and valence electron dynamics.
WD4 11:30 Contributed
Intra- and inter-band transitions in high harmonic generation from solids
T. Du, G. Jia, Xuebin. Bian, Wuhan Institute of Physics & Mathematics, WUHAN, HUBEI, CHINA|G. Jia,
Henan Normal University, Xinxiang, CHINA|T. Du, University of Chinese Academy of Sciences, Beijing,
CHINA|
A step-by-step model in k space was proposed to reveal the mechanisms of high harmonic generation in
solids. Inter- and intraband dynamics correspond to local and global oscillations of wavepackets at phase
and group velocities, respectively.
WD5 11:45 Contributed
Energy-dependent angular shifts in atomic ionization by elliptically polarized laser pulses
Min. LI, Huazhong Univ of Science and Technology, Wuhan, HUBEI, CHINA|
We measured photoelectron momentum distributions of atoms in elliptically polarized laser fields. We
found distinct energy-dependent angular shifts, which come from the ionization time delays among the
electrons with different energies.
46
WE Plenary session III
Wednesday, April 25, 2018, WE 13:30--15:00, Room 1
Xi-Cheng Zhang, University of Rochester, USA, Presider
WE1 13:30 Plenary
Recent Progress on terahertz source, modulation and its applications
Jianquan Yao, Tianjin University, Tianjin, China
The development of terahertz (THz) source and modulation facilitates a wider variety of applications.
This talk addresses our recent researches on THz sources based on THz parametric oscillator and
difference frequency generation and proposes a novel modulation technology that combines the
modulation of both the THz sources and devices. The works of THz applications in biomedical diagnostics
by transmission imaging, attenuated total reflection imaging and metamaterial based biosensors are
described as well, followed by summarization of the recent progress and prediction of the future trends
of THz technology.
WE2 14:15 Plenary
Generation, Characterization, and Applications of Single-cycle Laser Pulses
Kyung Taec. Kim, Institute for Basic Science, Gwangju, KOREA (THE REPUBLIC OF)
New methods for the generation and characterization of a single cycle laser pulse are presented. The
applications of the single cycle laser pulse on high harmonic generation and frustrated tunneling
ionization are also discussed.
47
WF Terahertz QCL
Wednesday, April 25, 2018, WF 15:20--17:15, Room 1
Chao Zhang, Wollongong University, Australia, Presider
WF1 15:20 Keynote
Terahertz semiconductor quantum devices and their applications
Juncheng. Cao, Shanghai Inst. Microsys. & Info. Tech., Shanghai, CHINA|
We demonstrate the transmission of real-time audio/video signal by using the THz QCL as a source in
continuous wave (cw) mode and the THz QWP as a receiver.
jProf. J. C. Cao received the Ph.D. degree in electrical engineering from the Southeast University, Nanjing,
China, in 1994. He is currently the Terahertz (THz) group leader of the Key Laboratory of Terahertz
Solid-State Technology at Shanghai Institute of Microsystem and Information Technology, Chinese
Academy of Sciences, China. His current research interests include THz semiconductor quantum devices
and their applications in THz communication and imaging.
WF2 15:50 Invited
The noise and modulation behaviors of Terahertz Quantum Cascade Lasers
Weidong. Chu, Inst Appl Physics & Computat Mathematics, Beijing, BEIJING, CHINA|
We studied the relative intensity noise and modulation properties of free-running, optical master-slave
injection and mutual injection THz-QCLs based on a three-level rate equation approach.
WF3 16:10 Invited
Terahertz Quantum Cascade Laser Frequency Comb and Fast Detection
Hua. Li, J. Cao, Chinese Academy of Sciences, Shanghai, CHINA|
We report the homogeneous spectral spanning of terahertz QCL frequency comb characterized by a kHz
level frequency stability and fast terahertz detection using a terahertz quantum well photodetector with
a bandwidth upto 6 GHz.
WF4 16:30 Contributed
Terahertz surface emission spectroscopy of layered MoS2 crystal: from surface optical rectification to
ultrafast photocurrent
Yuanyuan. Huang, L. Zhu, Z. Yao, L. Zhang, C. He, Q. Zhao, X. Xu, Northwest University, Xi'an, CHINA|
Terahertz radiation of layered MoS2 crystal under linear and circular polarized femtosecond laser
excitations was observed, and the surface optical rectification, photocurrent surge, as well as the helicity
dependent photocurrent were demonstrated.
WF5 16:45 Contributed
Multi-frequency terahertz surface wave lens based on double-layer metallic slit pairs
Minggui. Wei, X. Zhang, Y. Li, J. Gu, Z. Tian, J. Han, W. Zhang, Tianjin University, Tianjin, TIANJIN ,
CHINA|W. Zhang, Oklahoma State University, Stillwater, Oklahoma, UNITED STATES|
Here a surface wave lens (SWL) working at 0.6, 0.75 and 1 THz is demonstrated by using double-layer slit
pairs to simultaneously stimulate the surface wave and control their wavefronts by rotating the slit pairs.
WF6 17:00 Contributed
48
Silicon-based Terahertz Modulation and its Mechanisms
Zhaoji. Fang, C. XIA, D. KONG, C. Ruan, X. Wu, Beihang University, Beijing, BeiJIng, CHINA|Z. Li,
Max-Planck Institute for the Structure and Dynamics of Matter, Hamburg, GERMANY|N. Medvedev,
Institute of Physics AS CR, v.v.i., Prague, CZECHIA|N. Medvedev, Institute of Plasma Physics AS CR, v.v.i.,
Prague, CZECHIA|B. Wang, L. Wang, Chinese Academy of Sciences, Beijing, CHINA|B. Wang, University of
Chinese Academy of Sciences, Beijing, CHINA|
All-optical silicon-based terahertz amplitude modulation is experimentally and theoretically investigated.
Modulation depth >95% is achieved in 0.3-1.5 THz, which agrees well with Drude model, while plasmon
resonance is employed in 0.05-0.3 THz.
49
WG Terahertz science and technology in micro and
nano-structures III
Wednesday, April 25, 2018, WG 15:20--17:15, Room 3
Weiwei Liu, Nankai University, China, Presider
WG1 15:20 Keynote
Terahertz science of discrete and extreme matter
Alexander. Shkurinov, Moscow State University, Moscow, RUSSIAN FEDERATION|
We present results of our research on generation of terahertz radiation in liquid-like media, such as gas
clusters and liquefied gas, under the action of high power femtosecond laser pulses.
Alexander Shkurinov graduated in 1985 with honors from the M.V. Lomonosov Moscow State University
(MSU). Since 2004 he is a full-time Professor at the Department of Physics of the M.V.Lomonosov
Moscow State University, Moscow Russia where he is Head of the Laboratory of ultrafast processes in
Biology. The research interests of Alexander Shkurinov are mainly centered around the development and
application of femtosecond laser techniques, time-resolved spectroscopy of molecules in liquid phase,
nonlinear optics and THz techniques and spectroscopy. The results obtained by Alexander Shkurinov
have been published in more than 100 scientific papers in peer-reviewed journals. Throughout his career
Alexander Shkurinov has been participating and been part of advisory boards, organizing and program
committees of numerous international conferences. In 2008 The Russian Optical Society awarded
Alexander Shkurinov with the Medal in honor of Prof. Rozhdestvensky for his contribution into the
development of optical science and technology.
WG2 15:50 Invited
Metasurfaces for broadband terahertz linear polarization rotation and linear-to-circular polarization
conversion
Houtong. Chen, Los Alamos National Laboratory, Los Alamos, New Mexico, UNITED STATES|
We show metasurfaces consisting of few-layer anisotropic structures that allow for highly efficient and
broadband terahertz linear polarization rotation and linear-to-circular polarization conversion, operating
either in reflection or transmission.We show metasurfaces consisting of few-layer anisotropic structures
that allow for highly efficient and broadband terahertz linear polarization rotation and linear-to-circular
polarization conversion, operating either in reflection or transmission.
WG3 16:10 Invited
Fast THz Modulator based on the stagger-netlike metamaterial array nested with GaN HEMT
Yaxin. Zhang, Universityo Electronic Sci&Tech of China, Chengdu, SICHUAN, CHINA|
In this talk, we present a composite stagger-netlike metamaterial THz modulator that combines
optimized metallic metasurface with AlGaN/GaN heterostructure array to improve modulation speed
and depth. In the SMMTM, feeder circuits are simplified as far as possible and ingeniously integrated
into metamaterial structure, which significantly reduced parasitic factors of the modulator. By electrically
controlling the carrier concentration of 2DEG, resonant mode conversions between two different
analogous dipolar resonances have been realized. In real-time dynamic tests, this THz spatial modulator
achieves 93% modulation depth and 3 GHz modulation speed.
50
WG4 16:30 Contributed
Joint Measurement of THz Wave and Third-Harmonic Generation of Laser Filamentation in Air
K. Zhang , Y Jiang, University of Chinese Academy of Sciences, Beijing 100049, CHINA/ K. Zhang , Y.
Zhang, Tianming. Yan, Y Jiang, Shanghai Advanced Research Institute, Chinese Academy of Sciences,
Shanghai 201210, CHINA/ Y. Zhang, Center for Terahertz waves and College of Precision Instrument and
Optoelectronics Engineering, Key Laboratory of Opto-electronics Information and Technical Science,
Ministry of Education, Tianjin University, CHINA/ Y Jiang, School of Physical Science and Technology,
Shanghai Tech University, Shanghai 201210, CHINA
The origin of THz generation in dual-color laser fields is investigated by joint measurement of THz and
third-harmonic generation, showing the single-atom-ionization determined THz wave is modulated by
photocurrent behavior.
WG5 16:45 Contributed
Efficient terahertz radiation based on inverse spin Hall effect in W/CoFeB/Pt heterostructures
Shunnong. Zhang, Z. Jin, X. Lin, G. Ma, Shanghai University, Shanghai, CHINA|W. Zhu, Z. Zhang, Fudan
University, Shanghai, CHINA|J. yao, Tianjin University, Tianjin, CHINA|
We report the efficient broadband THz radiation in the metallic ferromagnetic W/CoFeB/Pt trilayer
heterostructures, upon irradiation of a fs laser pulse, which can be interpreted by a non-local spin
current pulses based on inverse spin Hall effect.
WG6 17:00
Contributed
Optically tuned optical properties of ferroelectric superlattice by THz spectroscopy
Jie. Ji, S. Zhou, Q. Chen, F. Ling, J. yao, Huazhong Univ of Science and Technology, Wuhan, HUBEI, CHINA|J.
yao, Tianjin University, Tianjin, CHINA|
Optical properties of ferroelectric superlattice film with different optical powers were characterized by
THz spectroscopy. Tunability of transmission could be tuned by 90.1%. Refractive index and absorption
coefficient was also varied along with it.
51
WH Ultra high intensity laser and its application
Wednesday, April 25, 2018, WH 15:20--17:15, Room 2
Jiansheng Liu, Shanghai Inst of Optics and Fine Mech, China, Presider
WH1 15:20 Keynote
Insight into laser-molecule interaction: from electronic structure to nuclear dynamics
P. Lan, L. He, Y. Zhou, Peixiang. Lu, Huazhong Univ of Science and Technology, Wuhan, HUBEI, CHINA|P.
Lan, Wuhan Institute of Technology, , Wuhan, CHINA|
High-order harmonic generation from molecules has been investigated in experiment. With the
high-harmonic spectroscopy method, we have achieved the tomographic imaging of molecular orbital,
attosecond probing of nuclear motion, and real-time observation of molecular spinning.
WH2 15:50 Invited
High Power Mid-Infrared Laser by DC-OPA
Eiji. Takahashi, RIKEN, Wako, SAITAMA, JAPAN|
We report the generation of high-power tunable mid-infrared laser pulses at 1 - 4 μm region with
duration of less than 70 fs, by a dual-chirped optical parametric amplification (DC-OPA) scheme.
WH3 16:10 Invited
Table-top Laser-driven microwire for Intense Terahertz radiation
Ye. Tian, J. Liu, Chinese Academy of Sciences, Jiading, ShangHai, CHINA|
We propose a novel terahertz source based on a femotosecond laser-driven microwire. This scheme can
produce intense THz sources with a conversion efficiency of 1%.
WH4 16:30 Contributed
Resonance-Enhanced Harmonics from Air Plasma Pumped by Mid-Infrared Femtosecond Pulses
Yi. Liu, R. Danylo, A. Houard, A. Mysyrowicz, Laboratoire d'Optique Appliquée, Palaiseau Cedex ,
FRANCE|Y. Liu, R. Danylo, Q. Liang, Z. Fan, X. Zhang, University of Shanghai for Science and Technology,
Shanghai, CHINA|M. Lei, A. Zhang, H. Jiang, C. Wu, Q. Gong, Peking University, Beijing, CHINA|V.
Tikhonchuk, Université de Bordeaux, Bordeaux, FRANCE|
Air pumped by mid-infrared femtosecond pulses gives rise to coherent emission at 391/428 nm. Based on
ellipticity dependence measurement and time-resolved characterization, we attribute this emission to
resonance-enhanced low order harmonics.
WH5 16:45 Contributed
Coherent intense soft x-ray high-order harmonics up to the water window generated by a loosely
focused infrared laser
Yuxi. Fu, K. Nishimura, K. Midorikawa, E.J. Takahashi, RIKEN, Wako, Saitama, JAPAN|A. Suda, Tokyo
University of Science, Noda-shi, Chiba, JAPAN|
Employing a TW-class infrared femtosecond laser (1.56 μm) for energy-scaling of high-order harmonics
under a loosely focusing geometry, we generate bright, coherent, ultrafast soft x-rays up to 285 eV in Ne
and 400 eV in He, respectively.
WH6 17:00 Contributed
52
Terawatt diode-pumped laser for intense Terahertz generation
Antoine. Courjaud, J. Brisset, P. Sevillano, Amplitude Systemes, Pessac, FRANCE|
We report on the laser development of a ytterbium based diode-pumped Terawatt-class laser delivering
500mJ 500fs @50Hz. The laser architecture is based on the combination of broadband Yb:CaF2
regenerative amplifier and Yb:YAG multipass amplifiers.
53
WI Poster session II (ultrafast phenomena) Wednesday April 25, 2018, WI 17:15--18:30, Room 2
WI1
Direct probing of tunneling time by time-dependent wave packet
M. Yuan, X. Bian, WIPM,CAS, Wuhan, HUBEI, CHINA|
An approach is presented to directly probe the tunneling time, where the influence of Coulomb potential
is avoided. A tunneling time of about 13 a.u. is obtained, which is almost not influenced by laser
intensities.
WI2
Optimizing Gas Pressure to Control Long Trajectory Phase Matching Produces Isolated Attosecond
Pulses
Y. Pan, Jilin University, Changchun, JILIN, CHINA|
We investigated the high-order harmonic generation(HHG) and propagation of Neon atoms exposed to
the mid-infrared laser pulse. At lower pressure, long trajectory satisfies phase matching conditions can
produce isolated attosecond pulses(IAP).
WI3
Interpulse interference of low energy photoelectron for atom irradiated by sinusoidally
phase-modulated pulses
D. Zhang, F. Guo, Y. Yang, Inst Atomic & Mol Physics, Jilin Univ, Changchun, JILin, CHINA|
We theoretically investigated the photoelectron emission of hydrogen atom irradiated by sinusoidally
phase-modulated pulses. Compared with the Fourier limit pulse, its photoelectron spectrum shows an
extra interference structure.
WI4
Multiexciton Relaxation in Quantum Dots Solids
L. Pan, Jilin University, Changchun, JILIN, CHINA|
Multiexciton relaxation were compared between monodispersed quantum dots (QDs) and quantum dot
solids (QDSs) by transient absorption. Relaxation rate is suppressed in QDSs. Electron percolating among
building QDs is consider to be the reason.
WI5
Interference effect of harmonic generation from aligned molecules manipulated by laser field
H. liang, Q. Wang, F. Liu, X. Fan, L. Shan, H. Xu, R. Ma, D. Ding, Ji Lin university, Changchun, JILin, CHINA|
We investigated aligned CO2 molecules in the Gaussian and non-Gaussian femtosecond pulses, which
brings different two-center interference effects. Changing of laser field is proved to be an effective
method to control harmonic generation.
WI6
The femtosecond pulse splitting in volume grating
X. Wang, X. Yan, H. Jiang, Z. Jin, Y. Dai, G. Ma, Lab. of Ultrafast Photonics, Department of Physics,
Shanghai University, Shanghai, CHINA|
Based on coupled-wave equations, the diffracted induced femtosecond splitting and its physical origin in
the volume grating are discussed. To get two pulses with different duration, we include the chirp in the
incident femtosecond pulse.
WI7
Dressed dynamics of optical dark pulse at group velocity horizon
Z. Deng, K. Wen, X. Wang, University of South China, HengYang, HUNAN, CHINA|
Optical event horizon provides a powerful tool to effectively manipulate the properties of dark soliton
54
with weak probe wave. By controlling the strength of probe wave we investigate the fundamental
feature of dark soliton.
WI8
Creation and storage of Picosecond Pulse train in Polariton BEC
Y. Xue, G. Wang, Jilin University, Chángchunshì, JILIN, CHINA|
We propose a scheme to generate and store the picosecond pulse in a non-resonant pumped polariton
BEC with the help of the coherent pump. Both the high efficiency and the high fidelity above 95% are
achieved.
WI9
Research on superimposed of 2 parallel high gain photoconductive semiconductor switches triggered
by laser
C. Ma, S. wang, W. Shi, Applied Physics Dept, Xi’an Univ of Tech, Xi'AN, CHINA|
The synchronization of the 2 parallel GaAs PCSSs is measured as 314.6 ps. In the output terminal,
superimposed by the output voltages of 2 parallel GaAs PCSSs, the total output voltage reaches up 2.3
times.
WI10
The stickiness effect of Hydrogen atom exposed to intense laser field evidenced by stable and unstable
manifolds
D. Wang, P. Wang, Capital Normal University, BeiJing, BEIJING, CHINA|
We investigated the ionization stabilization and the stickiness effect of Hydrogen atom exposed to
intense laser pulse. It is shown that the ionization of the one electron system is govern by the unstable
periodic orbit(UPO).
WI38
Comparison of spectral broadening methods in CEP stabilization
Y. Gao, Y. Liu, K. Zhao, S. Fang, Z. Wei, Institute of physics,CAS, Beijing, BeiJIng, CHINA|P. Huang, Xi’an
Institute of Optics and Precision Mechanics,CAS, Xi'an, CHINA|Y. Jiang, Xidian University, Xi'an, CHINA|S.
Xu, J. Wang, Beijing Jiaotong University, Beijing, CHINA|
We measured and stabilized the carrier-envelope phase with three different methods of supercontinuum
generation by f-2f spectral interferometry, finding that fused silica thin plates perfomed better than
sapphire plate and hollow-core fiber.
WI39
The application of double side Feynman diagram in strong-pump strong-probe spectroscopy
Z. Wang, Y. He, Q. Wang, Y. Zhang, B. Hu, Z. Liu, Lanzhou University, Lanzhou, GANSU, CHINA|
Based on double side Feynman diagram, an intuitive method is developed to explain sample's time
evolution in strong laser fields, which is used to study the dynamic evolution of the V-type three-level
system.
WI40
Pure Even Harmonic Generation from Oriented N2 in Two-color Field
Y. Yang, National University of Defense Technology, Changsha, CHINA|
In order to make it sure if permanent dipole moment results in the generation of pure even harmonics,
we investigate the HHG of nonpolar molecular N2 in two-color field using time-dependent Hartree-Fock
theory.
WI41
Terahertz emission of ZnO crystal driven by two-color laser
L. Liu, NUDT, Changsha, HuNan, CHINA|
Terahertz (THz) emission of crystal ZnO in a strong laser field and its second harmonics are simulated by
55
solving the semiconductor Bloch equations (SBEs), which describes the coupled interband and intraband
dynamics in two-band model.
WI46
CEO stabilized frequency comb from 1 um kerr lens modelocking laser using feed-forward scheme
Ziyue Zhang, Hainian Han, Xiaodong Shao, Zhiyi Wei,Beijing National Laboratory for Condensed Matter
Physics, Institute of Physics, Chinese Academy of Sciences, Beijing 100190, China/C.Huibo Wang, School
of Physics and Optoelectronics Engineering, Xidian University, Xian 710071, China
We have stabilized CEO frequency of a kerr lens mode locking Yb:CYA laser through feed forward
methods. 38 dB signal to noise ratio (SNR) of out-of-loop carrier envelop offset (CEO) beat signal was
obtained. Integrated phase noise was measured to be 80mrad when integrating from 1Hz to 1MHz. The
standard deviation of out-of-loop CEO frequency was maintained to be 12.2 mhz for more than 2 hours,
and Allan deviation was calculated to be 2.87×10-17.
56
WI Poster session II (THz waves) Tuesday, April 25, 2018, WI 17:15--18:30, Room 3
WI11
Terahertz artificial surface phonon polaritons
X. Zhang, Nanjing University, Nanjing, JIangSu, CHINA|
Surface phonon polaritons have advantages in terms of confinement and losses in the terahertz regime.
However, the working wavelengths of surface phonon polaritons are limited by materials. Here we
address this issue via piezoelectric metamaterials.
WI12
Towards Ultra-strong Terahertz Field Enhancement in Nanogap Split Ring Resonators
J. Cao, K. Chen, X. Wu, School of Electronic and Information Engineering, Beihang University, Beijing,
CHINA|B. Quan, B. Wang, L. Wang, Beijing National Laboratory for Condensed Matter Physics, Institute
of Physics, Chinese Academy of Sciences, Beijing, CHINA|B. Wang, School of Physical Sciences, University
of Chinese Academy of Sciences, Beijing, CHINA|
We design and fabricate terahertz split ring resonators with nanogaps for extremely high field
enhancement factor of >100000 when the splitting gap is sub-10 nm, and the experimental results agree
very with the simulated results.
WI13
Terahertz radiation from layered crystal and thin-film tungsten disulfide surface pumped by a
femtosecond laser
L. Zhang, Y. Huang, Q. Zhao, L. Zhu, Z. Yao, X. Xu, Northwest University, Xi'an, Shaanxi, CHINA|
Terahertz radiation from layered tungsten disulfide crystal and thin-film on substrates are investigated
experimentally. The results indicated different effect such as optical rectification and field effect.
WI14
Magnon Phonon Coupling Studies of Bi1-xNdxFeO3 Nanoparticles by Terahertz Time Domain
Spectroscopy
Y. Zhang, X. Zhong, Xiangtan university, XiangTan, Hunan, CHINA|Q. Guo, Z. Lu, D. Zhang, J. Yuan,
National University of Defense Technology, Changsha, CHINA|
Magnon-phonon coupling of Bi1-xNdxFeO3 (x=0~0.2) nanoparticles are studied by Terahertz time
domain spectroscopy. These nanoparticles show dopant concentration dependent electromagnons
coupling response with the maximum coupling at x=0.12.
WI15
Verification of the transparency of polystyrene multi-layer insulation using terahertz time domain
spectroscopy
B. Fan, Q. Shi, S. Shi, Sub-Millimeter Lab., Purple Mountain Observatory, Nanjing, Jiangsu, CHINA|B. Fan,
Q. Shi, School of Astronomy and Space Science, University of Sciences and Technology of China, Hefei,
Anhui, CHINA|
We measured the transmission characteristics of XPS-type RT-MLI and EPS-type RT-MLI with different
configuration. Comparing with the result on blocks, we confirm the reflectivity of XPS is lower than EPS
between 1 to 4 THz.
WI16
Terahertz spectroscopic identification of biomarker in renal fibrosis
J. Luo, Y. Peng, T. Kou, C. Shi, Y. Zhu, University of Shanghai for Science and Technology, Shanghai, CHINA|
L-hydroxyproline, an important biomarker in renal fibrosis, has been detected effectively in real rat
kidney tissue by THz time-domain spectroscopy (THz-TDS), which is especially meaningful for the
57
diagnoses of renal fibrosis.
WI17
Terahertz biosensing metasurface for DNA detection based on spoof surface plasmon polaritons
Z. Dang, Y. Chen, Y. Lin, Y. Wang, School of Physical, University of Electronic Science and Technology of
China, Chengdu, SiChuan, CHINA|D. Cheng, B. Zhang, G. Liu, Y. Luo, J. Wang, School of Electronic Science
and Engineering, University of Electronic Science and Technology of China, Chengdu, Sichuan, CHINA|G.
Shu, College of Electronic Science and Technology, Shenzhen University, Shenzhen, CHINA|
THz metasurface for DNA detection
WI18
LT-GaAs photoconductive antenna excited at 1550 nm for near-field terahertz detection
Yi Pan1, 2, Li Ding2, Jianbin He2, Zhu Zheng2, Qing Ding2, Yong Yao1,
1. Shenzhen institute of terahertz technology and innovation, Shenzhen, China.
2. Harbin Institute of Technology Shenzhen Graduate School, Shenzhen, China.
THz near-field imaging is an emerging technology for fundamental research and life science. We
presented a new near-field detection technique using LT-GaAs photoconductive antenna at 1550nm. The
system achieves 70dB dynamic range and 4THz bandwidth.
WI19
Ultraviolet light-induced terahertz modulation based on indium oxide thin film
H. Ji, B. Zhang, W. Wang, J.L. Shen, Capital Normal University, Beijing, CHINA|
An active ultraviolet light-induced terahertz modulation based on indium oxide thin film was investigated
in which exhibit a large absorption modulation of ~50% when illuminated by a low intensity UV laser (11
mW/cm2).
WI20
Combined experimental and theoretical terahertz spectroscopic study of cocrystallization between
piracetam and 2,5-dihydroxybenzoic acid
H. Lu, Q. Wang, Y. DU, China Jiliang University, Hangzhou, ZheJiang, CHINA|
Cocrystallization within piracetam and 2,5-dihydroxybenzoic acid was investigated by terahertz
spectroscopy and solid-state density functional theory(DFT).
WI21
Study on transmission loss of coplanar strip line
R. Wu, B. Su, J. Wang, J. He, S. Zhang, C. Zhang, Capital Normal University, Beijing, BeiJIng, CHINA|
In this paper, we studied the transmission loss of coplanar strip line with different parameters in THz
frequency through the software of HFSS. And the optimal structure of the coplanar strip line was
obtained.
WI22
Terahertz Metamaterials with low losses and high refractive index
X. Gao, School of Information and Telecommunication, Guilin University of Electronic Technology, Guilin,
Guangxi, CHINA|F.L. Yu, School of Information and Telecommunication, Guilin University of Electronic
Technology, Guilin, Guangxi, CHINA|
A Terahertz (THz) metamaterial that is formed by two-layer metasurface separated by a dielectric plate is
proposed to realize high refractive index and low loss in the frequency range from 0.2 to 2 THz.
WI23
Study on transmission characteristics of terahertz wave in microstrip line
Y. Zhao, B. Su, Y. Wen, J. He, C. Zhang, Capital Normal University, Bejing, CHINA|
A design of microstrip line (MSL) has been used for propagating terahertz wave through an on-chip
system. The ultimate aim of this article is to obtain the best parameters for the transmission of the THz
58
wave in the MSL using HFSS simulation software
WI24
Study on the Early Detection of Alzheimer's Disease Using Terahertz Spectroscopy
Y. Chen, Y. Wang, Z. Dang, Y. Lin, D. Cheng, B. Zhang, G. Liu, J. Wang, Y. Luo, University of Electronic
Science and Technology of China, Chengdu, SiChuan, CHINA|G. Shu, Shenzhen University, Shenzhen,
CHINA|X. He, X. Huang, Sichuan 81 Rehabilitation center Department of Integrated Tcm & Western
Medicine, Chengdu, CHINA|
We investigate the utility of terahertz (THz) spectroscopy in the field of detecting AD disease. The result
of simulation shows that THz has good resolution ability even in the early stage of AD.
WI25
A Wide-Angle and Polarization-Insensitive Perfect Terahertz Wave Absorber
W. He, X. Huang, F. Yang, J. Ran, S. Xie, B. Gao, Chongqing University, Chongqing, CHONGQING, CHINA|
A wide angle and polarization-insensitive metamaterial perfect absorber(MPAs) is proposed at terahertz
regime. The absorptivity of the MPAs keep more than 90% under all polarization angles and oblique
incidence.
WI26
Study of terahertz transmission on coplanar waveguide
Y. Wen, B. Su, Y. Zhao, J. He, C. Zhang, Captial Normal University, Beijing, CHINA|
The coplanar waveguide has relatively low radiation loss in the millimeter wave band. In this paper, we
find the most suitable coplanar waveguide structure parameters for the transmission of terahertz (THz)
using the software of Ansoft HFSS.
WI27
Detection and identification of liquids using reflection THz time-domain spectroscopy with principal
component analysis and support vector machine algorithm
X. Tan, S. Tang, Z. Yang, J. Xie, J. Tang, F. Xie, C. Qi, Terahertz Security Division, China Communication
Technology Co. Ltd., Shenzhen City, Guangdong, CHINA|
46 different kinds of liquids inside a quartz glass cell were measured with reflection THz-TDS. The sample
signals were analyzed with PCA and SVM algorithm in frequency domain and the liquids could be
identified feasibly.
WI28
Ultrafast all-optical tuning of terahertz waves in plasmonic metasurfaces
H. cai, University of Science and Technology of China, Hefei, Anhui, CHINA|Q. Huang, Y. Lu, University of
Science and Technology of China, Hefei, Anhui, CHINA|
We experimentally and theoretically demonstrate an ultrafast plasmonic metasurface consisting of
ion-implanted and annealed silicon disks in the terahertz range. The absolute transmission modulation is
38%, and the recovery time is about 200 ps.
WI29
Transmission modulation of lattice mode in U-shaped metamaterials
S. Yin, F. Hu, Guangxi Key Laboratory of Optoelectronic Information Processing, Guilin University of
Electronic Technology, Guilin, Guangxi, CHINA|
We demonstrate that the lattice mode can suppress the excitation of the high order mode of localized
surface plasmons in U-shaped metamaterials, which manifests the transmission modulation of lattice
mode in U-shaped metamaterials.
WI30
Toroidal dipole resonances based on four U-shape rings metamaterials in the terahertz regime
S. Wang, X. Zhao, J. Zhu, S. Wang, G. Nashon, Q. Li, TUTE, Tianjin, TIANJIN , CHINA|
59
we proposed and fabricated a planar terahertz metamaterials composed of four U-shape rings
resonators spacer with polyimide layers. Simulation and experimental results show that a toroidal
dipolar resonance at 0.75THz is acquired .
WI31
Characterization of the 70GHz photodiode via electro-optic sampling technique
G.Z. Feng, National institute of metrology of chIna, Beijing, BEIJING, CHINA|
We achieve the time-domain measurement of 70GHz photodiode basing on electro-optic sampling, and
analyze the frequency-domain characterization of the prepared LiTaO3-based electro-optic modulators
with coplanar waveguide structure.
WI32
Investigation on Terahertz time-domain spectroscopy in mixed rare earth orthoferrite
A. wu, Shanghai Institute of Ceramic,Chinese Academy of Sciences, Shanghai, CHINA|
Terahertz time-domain spectroscopy (THz-TDS) was used to study the ferromagnetic mode and
antiferromagnetic mode of mixed rare earth orthoferrites It demonstrates that THz-TDS is a sensitive
mean to explore the spin reorientation transition.
WI33
Investigation of graphene supported tunable PIT phenomenon in the THz regime
X. He, C. Shi, H. Zhang, Shanghai Normal University, Shanghai, SHanghai, CHINA|
The tunable THz plasmonic induced transparency has been explored based on the graphene-metal
hybrid structure, indicating that the obvious Fano peak can be observed and efficiently modulated, and
the amplitude modulation depth is about 40%.
WI34
Toward Topologically Manipulation of Terahertz Photoresponse in Layered Materials
J. Wang, C. Guo, L. Wang, X. Chen, W. Tang, W. Lu, National Laboratory for Infrared Physics, Shanghai
Institute of Technical Physics, Chinese Academy of Sciences, Shanghai, CHINA|C. Guo, L. Wang, X. Chen,
W. Tang, W. Lu, University of Chinese Academy of Science, Beijing, CHINA|J. Wang, Shanghai Normal
University, Shanghai, CHINA|
The joint presence of narrow bandgap and a 2DEG arising from topological surface states enables the
realization of excellent Ohmic contacts. We selected Bi2Se3 and TaSe2 to construct terahertz detectors
with high sponsivity and short response time.
WI35
Energy scaling of surface-emitted ring-cavity terahertz parametric oscillator with pump recycling
technique
L. Tang, D. Xu, Y. Wang, C. Yan, Y. He, C. Li, D. Yan, J. Shi, J. yao, Tianjin University, Tianjin, TIANJIN ,
CHINA|
The energy scaling of THz wave based on SE ring-cavity TPO with pump recycling technique have been
demonstrated. The tunable range was 1.38 to 3.42 THz. The maximum enhancement ratios of the
terahertz wave output power were 10.3 times at 1.38 THz.
WI36
High-energy and ultra-wideband tunable terahertz source with DAST crystal via difference frequency
generation
Y. He, Y. Wang, D. Xu, M. Nie, C. Yan, L. Tang, J. Shi, D. Yan, H. Liu, J. yao, Tianjin University, Tianjin,
TianJin, CHINA|B. Teng, Qingdao University, Qingdao, CHINA|
We have demonstrated a high-energy and broadly tunable terahertz (THz) source in DAST crystal. The
THz energy was related to the damage of the crystal. Furthermore, tests of transmission spectroscopy of
four typical samples were demonstrated.
60
WI37
Effects of micro/nano-structures on the photoelectric properties of silicon solar cell: A pump-probe
study
T. Chen, X. Wang, P. Han, Y. Zhang, Capital Normal University, Beijing, BeiJIng, CHINA|C. Zhang, University
of Wollongong, Wollongong, AUSTRIA|J. Lee, Hanyang University, Ansan, KOREA (THE REPUBLIC OF)|
We investigated the influence of the type of nanostructured surface and the doping impurity level on the
frequency-dependent dielectric response and photoconductivity of c-Si PV solar cells by using
femtosecond pump-THz probe spectroscopy techniques.
WI42
Generation of Rydberg Electrons and Terahertz Wave in Few Cycle Laser Pulses
J. Liu, L. Liu, W. Dong, Z. Zhao, J. Yuan, National Unversity of Defense Technology, Changsha, HuNan,
CHINA|
Two typical near-threshold processes in few cycle laser pulses, generation of Rydberg electrons and
Terahertz wave generation, are investigated using the Classical Trajectory Monte Carlo simulations.
WI43
Enhanced rotational absorption of polar molecule-formed plasma at THz frequency
Y. Huang, Z. Zhang, Advanced Interdiscriplinary Technology Research Center, National Innovation Institute
of Defense Technology, Beijing, CHINA|Y. Huang, Q. Guo, J. Zhao, J. Yuan, Z. Zhao, National University of
Defense Technology, Changsha, CHINA|J. Yuan, Graduate School of China Academy of Engineering
Physics, Beijing, CHINA|
We observe the enhanced THz absorption of the rotational transition lines within the resonant
absorption frequency range. Gas pressure is varied to show that the enhanced THz absorption lines are
related to the plasma frequencies.
WI44
440 GHz Turntable Imaging with a Regularization Method of Region-Based Feature Enhancement
S. Luo, J. Gao, B. Deng, Y. Qin, H. Wang, College of Electronic Science and Engineering, National University
of Defense Technology, Changsha, Hunan, CHINA|
A region-based feature enhancement imaging algorithm was applied for terahertz radar imaging,
reconstructing images with fewer speckles and a smoother surface than those obtained by traditional
Fourier-transform-based algorithms.
WI45
Frequency up-conversion of electromagnetic wave in a rapidly plasma for Terahertz wave
C. Chang, K. Chen, Key Laboratory for Physical Electronics and Devices of the Ministry of Education, Xi’an
Jiaotong University, Xi’an 710049, CHINA/ C. Chang, Science and Technology on High Power Microwave
Laboratory, Northwest Institute of Nuclear Technology, Xi’an, Shaanxi 710024, CHINA
Electromagnetic pulse propagation through a rapidly created plasma and frequency up-conversion has
been demonstrated by the particle-in-cell (PIC) and FDTD methods. The two methods could well
simulate the process of this issue about the interaction between the time-varying plasma and the
electromagnetic wave.
61
ThA Plenary session IV Thursday, April 26, 2018, 8:30--10:00
Huan Zhao, Capital Normal University, China, Presider
Jianmin Yuan,National University of Defense Technology,China,Presider
ThA1 8:30 Plenary
Recent Development on THz Aqueous Photonics
Xicheng. Zhang, U of Rochester, The Institute of Optics, Rochester, New York, UNITED STATES|
We demonstrated THz wave generation from liquid water in spite of its infamously strong absorption
characteristics. It is reasonable to expect that liquids might have unique properties if they could be
harnessed as THz sources.
Presider: Huan Zhao, Capital Normal University, China
ThA2 9:15 Plenary
Ultrafast Light Manipulation Using Photonic Micro/Nano-Structures
Qihuang. Gong, Peking University, Beijing, BEIJING, CHINA|
Micro/nano photonic structures permit remarkable control of the propagation of light. The
micro/nanoscale ultrafast light manipulation paves the way for the realization of various nanoscale
integrated photonic devices, which construct the essential basis of ultrahigh-speed and ultrawide-band
information processing chips. Moreover, for practical chip-integration applications, several significant
features, including on-chip trigger, ultrafast response, ultralow energy consumption, and wideband (or
multiple-wavelength) operation, are stringently required.
In this presentation, a selection of recent results will be presented. we realized an ultrafast, ultralow
power, on-chip-triggered 2x2 all-optical switch with multiple operating wavelengths based on
plasmon–photon hybrid nanostructures coated nonlinear multi-component nanocomposite material
formed directly in integrated photonic circuits. Low threshold pump intensity of 450 kW/cm2, fast
response of 63 ps, and multiple operating wavelengths were realized simultaneously. An ultralow-power
all-optical logic data distributor with dual address bits is also realized, based on a large nonlinearity
enhancement occurs in the nanocomposite material through resonant excitation via an upconversion
radiative-transfer process, which ensures an ultralow operating threshold control intensity of 10 kW/cm2.
An ultrafast response time of several picoseconds is simultaneously maintained based on structural
defects inducing ultrafast decay of excited-state carriers. Based on tunable Fano resonance or PIT of
metallic nanostructures, ultrafast modulations on light transmission were also demonstrated. Moreover,
ultracompact plasmonic devices including SPP unidirectional generator, splitter and others were
experimentally demonstrated.
Presider: Zengxiu Zhao, National University of Defense Technology, China
62
ThB Terahertz spectroscopy and imaging II
Thursday, April 26, 2018, 10:20--12:00
Jian Chen, Nanjing University, Presider
ThB1 10:20 Keynote
Commissioning and Operation of the First High Average Power Terahertz Free Electron Laser in China
Z. Xu, Sichuan Defense Science and Technology Industry Office, Chengdu, CHINA|X. Shu, Institute of
Applied Physics and Computational Mathematics, Beijing, CHINA|X. Lu, Institute of Heavy Ion Physics,
Peking University, Beijing, CHINA|W. Huang, Department of Engineering Physics, Tsinghua University,,
Beijing, CHINA|Ming. Li, X. Yang, D. Wu, Institute of Applied Electronics, Mian, SiChuan, CHINA|
This paper presents the first THz free electron laser in China. The terahertz laser’s frequency is
continuous adjustable from 2 THz to 3 THz. The macro-pulse average power is more than 10 W.
Professor Li graduated from Tsinghua University, and subsequently worked in Institute of Applied
Electronics till now, where he serves as the director of the free electron laser and THz department. His
research focuses on free electron laser technology, accelerator physics and technology, radiography
technology and applications, terahertz technology and other fields of scientific research. During his
researching time, he has presided over a number of scientific research projects such as the National
Major Scientific Instruments and Equipment Development Project, the 863 Program, and so on. Now
under his leadership, the china’s first high power THz source, which is based on Free electron laser and
can provide both high peak and average power radiation, has achieved remarkable success.
ThB2 10:50 Invited
Probing Interface Potential of Semiconductor Heterostructures with Laser Terahertz Emission
Spectroscopy
Iwao. Kawayama, Osaka University, Osaka, JAPAN|
I introduce recent studies on interface potentials of semiconductor heterostructures with laser terahertz
emission spectroscopy that measures THz emissions from materials and devices excited by femtosecond
laser pulses.
ThB3 11:10 Invited
Imaging on the Nanoscale with Terahertz Time-Domain and Emission Microscopy
Pemille. Klarskov Pedersen, A. Pizzuto, D.M. Mittleman, School of Engineering, Brown University,
Providence, Rhode Island, UNITED STATES|P. Klarskov Pedersen, DTU Fotonik, Technical University of
Denmark, Kgs. Lyngby, DENMARK|
We combine Laser Terahertz Emission Microscopy (LTEM) with terahertz time-domain nanoscopy in a
near-field microscopy configuration. With this, we demonstrate how the two techniques provide
complementary information about the sample.
ThB4 11:30 Contributed
The influence of Nb and Ti interface on DC characteristics of superconducting titanium transition edge
sensors
Yue. Geng, W. Zhang, Z. Wang, J. Zhong, W. Miao, Q. Yao, S. Shi, Purple Mountain Observatory, CAS,
Nanjing, JIANGSU , CHINA|W. Zhang, Z. Wang, J. Zhong, W. Miao, Q. Yao, S. Shi, Key Lab of Radio
Astronomy, CAS, Nanjing, CHINA|Y. Geng, University of Science and Technology of China, Hefei, CHINA|
63
TESs are attractive in quantum optics and quantum information experiments owing to high efficiency
and photon number resolving capability. We present the DC characteristics of TESs with different
overlapping area between Ti microbridge and Nb leads.
ThB5 11:45 Contributed
Influence of Oxygen Adsorption on the Terahertz Conductivity Spectroscopy of CVD-Grown MoS2 Thin
Flims
Xing. Xiao, Z. Zhang, X. Lin, Y. Yu, Z. Jin, G. Ma, Department of Physics, Shanghai University, Shanghai,
Shanghai, CHINA|X. xiao, International Collaborative Laboratory of 2D Materials for Optoelectronics
Science and Technology of Ministry of Education, College of Optoelectronic Engineering, Shenzhen
University, Shenzhen, Guangdong, CHINA|L. Zhao, State Key Laboratory of Precision Spectroscopy, East
China Normal University, Shanghai, Shanghai, CHINA|J. yao, College of Precision Instrument and
Optoelectronics Engineering,Key Laboratory of Optoelectronics Information and Technology (Ministry of
Education), Tianjin University, Tianjin, Tianjin, CHINA|
By employing the time-resolved terahertz spectroscopy, we have investigated the dynamical
photoconductivity response of MoS2 laminate in nitrogen, dry air and oxygen, the photoconductivity of
MoS2 is dramatically altered by the adsorption of oxygen.
64
ThC Terahertz science and technology in micro and
nano-structures IV Thursday, April 26, 2018, 10:20--12:00
Hou-Tong Chen, Los Alamos National Laboratory, USA, Presider
ThC1 10:20 Keynote
Terahertz Driven Accelerators
Franz. Kaertner, Physics Department, Universität Hamburg, Hamburg, GERMANY|F.X. Kaertner, Center for
Free-Electron Laser Science, DESY, Hamburg, GERMANY|
High-energy THz pulse generation and approaches towards linear THz accelerators are discussed and
demonstrated. First results from THz guns and accelerators are shown and concepts for compact X-ray
sources based on these devices are presented.
Franz Kärtner heads the Ultrafast Optics and X-rays Group at the Center for Free-Electron Laser Science
at DESY and is Professor of Physics at University of Hamburg. Within an ERC Synergy Grant, he and
colleagues pursue Terahertz acceleration and coherent X-ray sources. He is a fellow of OSA and IEEE.
ThC2 10:50 Invited
Terahertz super-focusing based on chiralty plasmonics
Yiming. Zhu, Shanghai Inst. of Science and Technology, Shanghai, CHINA|
A planar chirality spiral plsmonic lens that owns the capability of realizing polarization-controlled
terahertz super-focusing, is proposed. The full wave at half maximum (FWHM) of the hot-spot is almost
0.38λ, breaking the diffraction limit.
ThC3 11:10 Invited
Manipulating terahertz wavefront using all-silicon dielectric metasurfaces
H. Zhang, Q. Xu, Xueqian. Zhang, J. Han, W. Zhang, Tianjin University, Tianjin, CHINA|
In this talk, we will present our recent studies on efficient terahertz wavefront control using all-silicon
dielectric metasurfaces, including polarization-independent and -dependent anomalous refraction,
focusing, and special beam generation, etc.
ThC4 11:30 Contributed
Demonstration of Orbital Angular Momentum Multiplexing and Demultiplexing Based on Metasurface
in Terahertz Band
Huan. Zhao, X. Wang, Y. Zhang, Capital Normal University, Beijing, CHINA|B. Quan, C. Gu, J. Li, Chinese
Academy of Sciences, Beijing, CHINA|
In this work, OAM (de)multiplexing based on a single layer metasurface has been demonstrated
numerically and experimentally. The designed structure realized OAM multiplexing or demultiplexing
under the incident Gaussian beam or vortex beam.
ThC5 11:45 Contributed
Polarization-Dependent Terahertz Metasurfaces
Shiwei. Qu, H. Yi, Univ of Electronic Science & Tech China, Chengdu, SICHUAN, CHINA|C.H. Chan,
Electronic Engineering, City University of Hong Kong, Hong Kong, CHINA|
In this paper, two kinds of polarization-dependent metasurfaces are proposed for wavefront
manipulation. The results of the proposed polarization-dependent metasurfaces are illustrated in detail
while their operating principles are also given.
65
ThD Terahertz spectroscopy and imaging III
Thursday, April 26, 2018, 10:20--12:00
Cunlin Zhang, Capital Normal University, Beijing, CHINA, Presider
ThD1 10:20 Keynote
Optical frequency combs for precision spectroscopy from near-infrared to Terahertz
Heping. Zeng, East China Normal University, Shanghai, SHANGHAI, CHINA|
Optical frequency combs have revolutionized the approach to laser spectroscopy and thus had profound
impact on molecular sensing and imaging. Here, several methods for optical comb generation from the
near-infrared to Terahertz regions are reviewed. Their applications in molecular fingerprinting with
asynchronized laser combs (also dual-comb spectroscopy) are discussed.
Heping Zeng received the B.S. degree in physics from Peking University, Beijing, China, in 1990 and the
Ph.D. degree from the Shanghai Institute of Optics and Fine Mechanics, Chinese Academy of Science,
Shanghai, China, in 1995. Currently, he is a Professor in East China Normal University, China. His research
interests include ultrafast photonics, Terahertz optics, optical frequency combs and single-photon optics.
So far, he has published more than 250 papers in peer-reviewed journals including Phys. Rev. Lett., Appl.
Phys. Lett., Opt. Lett. Phys., Rev. A, Opt. Express and so on. In 2006, Prof. Zeng has been elected Fellow of
OSA, the Optical Society, “for significant contributions to the understanding of ultrafast molecular
processes in intense laser fields, and for sustained technical development of high-power ultrashort fiber
lasers and infrared single-photon detection.”
ThD2 10:50 Invited
Terahertz micro-nano structure devices for phase and polarization control
Shengjiang. Chang, Nankai University, Tianjin, TianJin, CHINA|
Terahertz (THz) application systems have an urgent demand on efficient THz phase and polarization
devices. This report will introduce broadband polarization convertors and tunable phase shifters based
on well-designed THz metasurfaces and tunable materials.
ThD3 11:10 Invited
Development of THz Emitters and Detectors for Femtosecond-Fiber-Laser-Based Terahertz
Time-Domain Spectroscopy
Masahiko Tani, University of Fukui, Fukui, FUKUI, JAPAN|
For realization of low-cost THz time-domain spectroscopy system, the use of femtosecond fiber lasers
are highly preferable. This paper reports development of THz emitters and detectors usable with
1550-nm femtosecond fiber lasers.
ThD4 11:30 Contributed
Visualizing Interference Structure with Attosecond Temporal Resolution
Weifeng Yang, Shantou University, Shantou, GUANGDONG, CHINA|
We developed a GQTMC method which could apply to arbitrary values of the Keldysh parameter. It
provides an efficient way to probe the interference structures and the underlying electronic dynamics in
photoelectron momentum distribution.
66
ThD5 11:45 Contributed
CEP-stabilized, sub-18 fs, dual output at 10 kHz and TW-class 1 kHz Ti: Sa laser with an original
front-end design
Xiaowei. Chen, A. Golinelli, B. Bussière, E. Gontier, Lisses operations, Amplitude laser group, Evry,
FRANCE|A. Golinelli, O. Tcherbakoff, P. d'Oliveira, LIDYL, CEA-SACLAY, Gif-sur-Yvette, FRANCE|P. Paul, San
Jose operations, Amplitude laser group, San Jose, California, UNITED STATES|
We present a Ti: Sa based 1 kHz TW-class laser system with an original 10 kHz front-end design,
delivering 17.8 fs pulses at with 350 mrad shot to shot residual CEP noise.
67
Author Index
A
Ang,L. •WC3
Ang,Y. •WC3
B
Baghery,Mehrdad•TuJ3
Bai,Ya •TuK42
Balakin,Alexei V. •WG1
Becker,Wilhelm•TuJ4
Bian,XueBin•WI1,WD4
Brisset,Jean-Gabriel•WH6
Bussière, B. •ThD5
C
Cai,Honglei•WI28
Cai,Qiang •TuK44
Cai,Yi•TuB2
Cao,J. •WF1
Cao,J. C. •TuK38,TuK38,TuK15,TuK29
Cao,Jiahui•WI12
Cao,Shixun•TuH3
Cao,Wei•WD5
Chai,Shusu•TuB3
Chan,Chi Hou•ThC5
Chang,C•WI45
Chang,Shengjiang •ThD2
Chang,Tianying•TuK40
Chen,H. •WG2
Chen,J. •WD1
Chen,Jing•TuJ4
Chen,Jiong•TuK8
Chen,K•WI45
Chen,Kanglong•TuK36,WI12
Chen,Liming•TuE5
Chen,Min•TuE5
Chen,Qijun•WG6
Chen,T•WI37
Chen,Tunan•TuF5
Chen,Xin•WI34,ThD5,TuK11
Chen,Xiren•TuH1
Chen,Yanping•TuE5
Chen,Yuqi•TuK28,WI17,WI24
Cheng,Dong•TuK28,WI17,WI24,WB3
Cheng,Y. •WD1
Cheng,Zhenxiang•TuH3
Chu,Junhao•TuH1
Chu,W. •WD1
Chu,Weidong•WF2
Courjaud,Antoine•WH6
Cui,Hong-Liang•TuK40
Cui,Sen•TuE5
Cui,Suochao•TuK8
Cui,T. •TuA2
Cutler,P. H. •WC5
D
Dai,Jiayu •WH3
Dai,Ye•WI6
Dang,Zhangqi •TuK28,WI17,WI24
Danylo,Rostyslav•WH4
Deng,Bin•WI44,TuK16,WB4
Deng,Derong•ThB1
Deng,Qing hua •TuK21
Deng,Zhixiang •WI7
Ding,Dajun•WD2,WI5,WI2
Ding,Li•WI18
Ding,Qing•WI18
d'Oliveira, Pascal•ThD5
Dong,Chengang•TuK5,TuK45
Dong,Jiangpeng•TuC3
Dong,Wenpu•TuK1,TuK7
Du,Tao-Yuan•WD4
Du,Yong•WI20,TuK44
Duan,Danni•TuK5
Dzhidzhoev,Murat S. •WG1
E
E,Y.W. •ThA1
F
Fan,B.W. •WI15
Fan,Fei•ThD2
Fan,Xiaohu•TuK4
Fan,Xin•WI5
Fan,Zhengquan•WH4
Fang,S•WI38
Fang,Shaobo•TuG4
Fang,Zhaoji•TuK39,WF6
Feng,Hua•TuF5
68
Feng,Shengfei•TuK20
Feng,Zhigang•WI31
Fu,Yuxi•WH5
G
Gan,Zebiao•WA2
Gao,Bin•WI25
Gao,Jia•WI44,TuK40
Gao,Jingkun•WB4
Gao,Xi•WI22
Gao,Yitan •TuG4
Gao,Z•WI38
Geng,Y. •ThB4
Georges,Patrick •TuK3
Giri,Sajal Kumar•TuJ3
Gleichweit,Christoph•WB5
Golinelli,A. •ThD5
Gong,Q. •ThA2
Gong,Qihuang•WH4
Gontier,E. •ThD5
González,A. I. •TuK3
Gordienko, VyacheslavM. •WG1
Gu,Changzhi•ThC4,ThD3
Gu,Jianqiang•TuI4,TuK26,WF5
Guichard,F. •TuK3
Guo,C•WI34
Guo,Chucai•TuK31
Guo,Fu-Ming•WI2, WI3
Guo,Quan•WI43,TuK14,TuK22,WI14
H
Han,Hainian• WI46
Han,Jiaguang•ThC3,TuI4,TuK26,WF5
Han,Peng•WI37,TuK20
Hang,Yin•WA2
Hanna,M. •TuK3
Hao,Qiang•TuK6
Hao,XiaoLei•TuJ4
He,Chuan•WF4
He,Feng•TuE5
He,Huijun•TuG1
He,Jianbing•WI18
He,Jingsuo•WI21,TuK23,TuK32,TuK41,WI23,WI2
6
He,L. •WH1
He,Lixin•TuK2
He,Tianhui•ThB1
He,Wei•WI25
He,Xia•WI24
He,Xiaoyong•WI33
He,Xinkui• TuG4
He,Y•WI35,WI36,WI39
Hebling,János•TuI1
Hegmann,F.A. •WA1
Hergott,J.F. •ThD5
Hirakawa,K. •TuC1
Hirakawa,Kazuhiko•WC2
Holzwarth,Ronald•WB5
Hou,Lei•TuK35
Hou,Xun• TuG4
Hou,Yanbing•TuK49
Houard,Aurélien•WH4
Hu,B•WI39
Hu,Fangrong•WI29
Hu,Guoqing•WC1
Hu,L. X. •TuG3
Huang,Hangdong• TuG4
Huang,P•WI38
Huang,Pei•TuG4
Huang,Qiuping•WI28
Huang,Wenhui•ThB1
Huang,Xialian•WI24
Huang,Xiaoyi•TuK44
Huang,Xin•WI25
Huang,Yindong•TuK7,TuK14,TuK22
Huang,Yuan•TuK39
Huang,Yuanyuan•WI13,WF4
Huang,Z•WI43
I
Ivanov,Igor E. •WG1
J
Jang,Dogeun•TuE2
Ji,Hongyu•TuK33,TuK34,TuK49,WI19
Ji,Jie•TuK37,WG6
Jia,Guang-Rui•WD4
Jia,M. W. •WC4
Jiang,Hongbing•WH4
Jiang,Hongru•WI6
Jiang,Huachao•TuH4
Jiang,Tao•TuK21
Jiang,Y•WI38
Jiang,Y.H. •WG4
69
Jiang,Yujiao•TuG4
Jie,Wanqi•TuC3
Jin,Biao-Bing•TuF3
Jin,Minxing•WD2
Jin,Q. •ThA1
Jin,Zuanming•ThB5,TuK18,TuH3,TuK9,TuK11,WG
5,WI6
Jing,Chao•TuH3
K
Kang,Dongdong•WH3
Kärtner,Franz X.•ThC1
Kawase,Kodo•TuH2
Kawayama,Iwao•TuF2,ThB2
Kim,K. •WE2
Kim,Ki-Yong•TuE2
Klarskov,Pernille •ThB3
Kong,Deyin•TuB3,TuK36,TuK24,WF6
Kotelnikov,Igor A. •WG1
Kou,Tianyi•WI16
Ku,Zhiliang•TuK18
Kuzechkin,Nikolay A. •WG1
L
Lai,XuanYang•TuJ4
Lan,Feng•TuK25,TuK30
Lan,P. •WH1
Lan,Pengfei•TuK2
Lao,Chenglong•ThB1
Lavenu,L. •TuK3
Lei,Mingwei•WH4
Leng,Yuxin•WA2
Lerner,P. B. •WC5
Li ,Hua•WF3
Li ,Ruxin•WA2
Li,C•WI35
Li,H. •TuK15,TuK29,TuK47
Li,H. Z. •TuG3
Li,Hai•TuK6
Li,Heting•TuK20
Li,Jiang•TuF4
Li,Jugeng•TuK11
Li,Junjie•ThC4,ThD3
Li,M. •TuG5
Li,Min•WD5
Li,Ming•ThB1,TuK17
Li,Peng•ThB1,TuK17
Li,Quan•TuK43,WI30
Li,Shangqin•TuB3
Li,WeiDong•TuJ4
Li,Weihua•TuK21
Li,Wenqi•WA2
Li,Y.T. •TuE4
Li,Yanfeng•TuI4,TuK26,WF5
Li,Yang•WD5
Li,Yuanyuan•WF2
Li,Yutong•TuB3,TuE1
Li,Z. P. •TuK29
Li,Zheng•TuK39
Liang,Dachuan•TuK26
Liang,Hongjing•WI5
Liang,Qingqing•WH4
Liang,Xiaoyan•WA2
Liao,Guoqian•TuE1
Lin,Baoqing•TuK13
Lin,Ke•TuK46
Lin,Qinggang•TuB2
Lin,Sifen•ThB1
Lin,Xian•ThB5,TuH3,TuK9,WG5,TuK11,TuK18
Lin,Yuxing•WI17,TuK28,WI24
Lin,Zhiyang•TuK13
Lindenberg,A.M. •WE1
Ling,Furi•TuK37,WG6
Liu, Lu•TuK7
Liu,Chengpu•TuK42
Liu,Dandan•TuK33,TuK49
Liu,Fangyuan•WI5
Liu,Guo•TuK28,WI17,WI24
Liu,H•WI36
Liu,Hongwei•TuK46
Liu,Jiansheng•TuG2
Liu,Jian-xun•TuK10
Liu,Jie•ThB1
Liu,Jinlei•TuK1,TuK7,WI42
Liu,Jinsong•TuK27
Liu,Ken•TuK31
Liu,L•WI41
Liu,Lingyu•TuK40
Liu,Lu•TuK1,WI42
Liu,Peng•TuK42
Liu,Qi•WB4,TuK9
Liu,Qiao•TuF4
70
Liu,XiaoJun•TuJ4
Liu,Xin•TuK34
Liu,Xiumei•TuH3
Liu,Y•WI38
Liu,Y. P. •WC4
Liu,Yangyang•TuG4
Liu,Yanqi•WA2
Liu,Yi•WH4
Liu,Yunquan•TuJ1
Liu,Z•WI39,WD1
Lohninger,H. •WB5
Lu,Hao•WI20
Lu,P. •WH1
Lu,Peixiang•TuK2,WD5
Lu,W•WI34
Lu,Wei•TuH1
Lu,Xiangyang•ThB1
Lu,Y. •TuG3
Lu,Yalin•WI28
Lu,Zhihui•WI14
Luo,Feng•TuK25
Luo,Jie•WI16
Luo,S•WI44
Luo,Siqiang•WD5
Luo,Xing•ThB1
Luo,Yong•WI24,TuK28,WI17
Lv,Hang•WD2
Lv,Li-ping•TuK9
Lv,Longfeng •WI19
Lv,Zhihui•TuK1,TuK14,TuK22
M
Ma,Cheng•WI9
Ma,Guohong•ThB5,TuH3,TuK9,TuK11,TuK18,WG
5,WI6
Ma,Jinglong•TuB3
Ma,Qian•WH3
Ma,Ri•WI5
Ma,S. J. •WC4
Ma,Yan-yun•TuK10
Ma,Z. •WC3
Matsuda,Aleph•WC2
Matsuda,Eiki•TuF2
Mazumder,Pinaki•TuK30,TuK25
McKenna,Paul•TuE1
Medvedev,Nikita•WF6
Meng,Chao•TuK14
Meng,Congsen •TuK1,TuK14
Meng,Xianghao•TuG1
Miao,Jingyuan•WI31
Miao,Jungang•TuB3
Miao,W. •ThB4
Midorikawa,Katsumi•WH5
Misawa,Hiroaki•TuD3
Miskovsky,N. M. •WC5
Mittleman,Daniel M. •ThB3
Mottay,Eric •TuK3
Murakami,Hironaru•TuF2
Murate,Kosuke•TuH2
Mysyrowicz,André•WH4
N
Naka, Akiyoshi•WC2
Nashon,Gati•WI30
Natile,M. •TuK3
Neely,David•TuE1
Ng,A. •TuD2
Nie,M•WI36
Nie,Tianxiao•TuK24
Ning,Qicheng•TuJ3
Nishimura,Kotaro•WH5
O
Okada,Kosuke•TuF2
Ouyang,Chunmei•TuI4,TuK26
Ozaki,T. •TuB1
P
Pan,C. •WB2
Pan,Lingyun•WI4
Pan,Yi•WI18
Pan,Yun•WI2
Paul,P.M. •ThD5
Peng,Yan•WI16
Peters,Ole•WB5
Pickwell-MacPherson, Emma•TuF1
Pizzuto,Angela•ThB3
Q
Qi,Chunchao•WI27
Qi,J.•WC4
Qin,Hua•TuC2
Qin,Y•WI44
Qin,Yuliang•TuK16
Qu,Shi-Wei•ThC5
71
Quan,Baogang•TuK36,ThC4,ThD3,WI12
Quan,Wei•TuJ4
Ran,Jia•WI25
Rost,Jan-Michael •TuJ3
Ruan,Cunjun•TuB3,TuK36,TuK24,WF6,TuK23,TuK
32,TuK41,WI21,WI23,WI26
Ruchon,T.•TuK3
S
Saalmann,Ulf •TuJ3
Schneider,H. •TuA1
Serita,Kazunori•TuF2
Sevillano,Pierre•WH6
Shan,Lijun•ThB1
Shan,Liyu•WI5
Shao,F. Q. •TuG3
Shao,Jun•TuH1
Shao,Xiaodong• WI46
Shen,Changle•TuK21
Shen,Jingling•TuK33,TuK34,TuK49,WI19
Shen,Xuming•ThB1
Sheng,Z.M. •TuE4
Sheng,Zhengming •TuE1,TuE5
Shi,Chengjun•WI16
Shi,Chenyuyi•WI33
Shi,Huafeng•TuK19
Shi,J•WI35,WI36
Shi,jinxin•TuK48
Shi,Q.•WI15
Shi,S.•WB1
Shi,S.C.•ThB4,WI15
Shi,Wei•TuK5,TuK45,TuK35,WI9
Shi,Zexia•TuK41
Shi,Zongjun•TuK48
Shkurinov,Alexander•WG1
Shu,GuoXiang•WI24,TuK28,WI17
Shu,Xiaojian•ThB1
Singh,R. •TuI3
Solyankin,Peter M. •WG1
Song,Pan•TuK1
Su,Bo•WI21,TuK23,TuK32,TuK41,WI23,WI26
Su,Fuhai•TuH4
Suda,Akira•WH5
Sun,Feng•TuK8
Sun,Jiandong•TuC2
Sun,Qiushuo•TuF1
Sun,Quan•TuD3
Sun,Wenfeng•TuK20
Sun,Xiaowei•TuK19
T
Takahashi,Eiji J. •WH2,WH5
Tamai,Naoto•WI4
Tan,Xinhui•WI27
Tang,Jianmin•WI27
Tang,K•WI35
Tang,L•WI36
Tang,Shana•WI27
Tang,W•WI34
Tang,Z. K. •TuK47
Tcherbakoff,O.•ThD5
Tcypkin, A. •ThA1
Teichert,Christian•TuC3
Teng,B•WI36
Teng,Hao•TuG4
Teng,Jinghua•TuI2
Tian,Wenlong•TuG1
Tian,Ye •TuG2
Tian,Yue•TuK37
Tian,Zhen•TuK26,WF5,TuI4
Tikhonchuk,Vladimir•WH4
Tonouch,Masayoshi•TuF2
Tu,Yanyun•TuK12,TuK14
U
Ueno,Kosei•TuD3
Unuma,Takeya•WC2
W
Wan,W. J. •TuK15,TuK29
Wang•WI39
Wang, Ji•TuG4
Wang,Baoning•TuK2
Wang,Bo•TuK24,TuK39,WF6,WI12,WI19
Wang,Cheng•WA2
Wang,Ding•WI10
Wang,F. •TuK38
Wang,Gang•WI8
Wang,Guocui•TuK49,WI19
Wang,H•WI44
Wang,Hai•TuK41
Wang,Hanbin•ThB1
Wang,Honggeng•TuK42
Wang,Hongqiang•TuK16,WB4
72
Wang,Huibo• WI46
Wang,J•WI34,WI38
Wang,Ji• TuG4
Wang,Jiahui•WI21
Wang,JianGuo•TuJ4
Wang,Jianxin•ThB1
Wang,Jianxun•WI17,WI24
Wang,Jiarui•TuF1
Wang,Kejia•TuK27
Wang,L•WI34
Wang,Li•TuK24,TuK39,WF6,WI4,WI12
Wang,Ling•TuK45
Wang,Peijie•WI10
Wang,Q•WI39
Wang,Qiaoxia•WI5
Wang,Qiqi•WI20
Wang,Sen•TuK20
Wang,Shaoqiang•WI9,TuK5,TuK45,TuK32,WI21
Wang,Shuang•TuK43,WI30
Wang,Song•WI30
Wang,W.M. •TuE4
Wang,Wei•TuK34,TuK49,WI19,TuK33
Wang,X•WI37
Wang,Xiaowei•TuK1,TuK4,TuK14
Wang,Xiaoyan•WI6
Wang,Xinke•TuK20,ThC4,ThD3,WI7
Wang,Xuemin•TuK21
Wang,Y•WI35,WI36
Wang,YanLan•TuJ4
Wang,Yao•TuK28,WI17,WI24
Wang,Yuye•TuF5
Wang,Z. •ThB4,WC4
Wang,Zhanshan •TuK42
Wang,Zhaohua•TuG1
Wang, Zhenwei•TuK12
Wei,Minggui•WF5
Wei,Z•WI38
Wei,Zhiyi•TuG1,TuG4, WI46
Wen,Kui•WI7
Wen,Yiwei•WI23,WI26
Wong,Kam Sing•TuD1
Wu,Anhua•TuK11,WI32
Wu,Chengyin•WH4
Wu,Dai•ThB1,TuK17
Wu,Erheng•TuK42
Wu,J. •TuJ2
Wu,R. Q. •WC4
Wu,Rui•WI21
Wu,Weidong•TuK21
Wu,Xiaojun•TuB3,TuK24,TuK36,TuK39,WF6,WI12
Wu,Xiaolei•TuK32
Wu,Y. Z. •WC4
Wu,Yaxiong•TuK32
Wu,Yong•TuJ4
X
Xia,Chenyi•TuK39WF6
Xiang,Feidi•TuK27
Xiao,Bao•TuC3
Xiao,Dexin•TuK17,ThB1
Xiao,Meng•TuK36
Xie,Fangqi•WI27
Xie,Hui•WD5
Xie,Junzhong•WI27
Xie,Shengyi•WI25
Xing,Xiao•ThB5
Xiong,Luyao•TuK34
Xiong,Zikang•TuK23
Xu ,Yong•ThB1
Xu,B. •WD1
Xu,D•WI35,WI36
Xu,Degang•TuF5
Xu,Haifeng•WD2,WI5
Xu,Quan•ThC3,TuI4
Xu,S•WI38
Xu,Shixiang•TuB2
Xu,Shujuan•TuH4
Xu,Siyun•TuG4
Xu,Tie•TuK43
Xu,Wei•TuK31
Xu,Xinlong•WF4,WI13
Xu,Yadong•TuC3
Xu,Yong•TuK17
Xu,Yuehong•TuI4
Xu,Zhizhan•WA2
Xu,Zhou•ThB1
Xue ,Yan •WI8
Y
Yan,C•WI35,WI36
Yan,D•WI35,WI36
Yan,Huijie•TuK18
73
Yan,Tian-Min•WG4
Yan,Xiaona•WI6
Yang,Fan•WI25
Yang,Kangwen•TuK6
Yang,Lei•TuK5,TuK45
Yang,Ning•WF2
Yang,Qi•TuK16,WB4
Yang,Rui•TuK31
Yang,Weifeng•ThD4
Yang,Xinfan•TuK17
Yang,Xiuwei•TuK40
Yang,Y•WI40
Yang,Yu-Jun•WI2,WI3
Yang, Zhengang •TuK27,WI27
Yang,Ziqiang•TuK30
Yao,J•WI35,WI36,WD1
Yao,Jianquan•WG5,ThB5,TuF5,TuH3,TuK9,WG6
Yao,Q.J. •ThB4
Yao,Yong•WI18
Yao,Zehan•WI13,WF4
Yasui,Takeshi•WC1
Ye,Jiasheng•TuK20
Ye,Pengbo•TuK6
Yi ,Huan•ThC5
Yin,Shan•WI29
Yin,Y.•TuG3
Yoo,Yungjun•TuE2
Yu,Fa Long•WI22
Yu,Jin•TuE5
Yu,Lianghong•WA2
Yu,T. P. •TuG3,TuK10
Yu,Wenfeng•TuK37
Yu,Yang•ThB5
Yu,Yao•TuC2
Yuan ,MingHu•WI1
Yuan,Jianmin•TuK1,TuK14,TuK22,WD3,WH3,WI1
4,WI42,WI43
Yuan,Xiaodong•TuK31
Yuan,Yinghao•TuK8
Z
Zaouter,Y.•TuK3
Zeng,H. •ThD1
Zeng,Heping•TuK6
Zeng,Hongxin•TuK30
Zeng,Jiaolong•TuK4
Zeng,Xuanke•TuB2
Zhai,Chunyang•TuK2
Zhan,Zhiqiang•TuK21
Zhang ,Di-Yu•WI3
Zhang,An•WH4
Zhang,Bao•TuK28,WI17,WI24
Zhang,Baolong•TuB3
Zhang,Bin-bin•TuC3
Zhang,Bo•TuK23,TuK33,TuK34,TuK49
Zhang,C. •TuE3,WC3
Zhang,C.L. •TuE4
Zhang,Cheng•WB3
Zhang,Dongwen•TuK4,TuK1,TuK12,TuK14,TuK22,
WI14,WI42
Zhang,Hao •WI33
Zhang,Hongying•TuK16,WB4
Zhang,Huifang•TuK26,ThC3
Zhang,J. •TuE4
Zhang,Jiadong•TuK11
Zhang,Jianfa•TuK31
Zhang,Jie•TuE1,TuE5
Zhang,Kai-Xuan•WG4
Zhang,L.L. •ThA1,TuE4
Zhang,Lei•WI11
Zhang,Longhui•WF4,WI13
Zhang,Peng•ThB1,TuK17
Zhang,Qi•TuK44
Zhang,Qingbin•TuK2
Zhang,Shunnong•TuH3,WG5
Zhang,Sitao•TuK9
Zhang,W. •ThB4
Zhang,Weili•ThC3,TuI4,TuK26,WF5
Zhang,Wenjie•TuK9
Zhang,X. H. •TuK47
Zhang,X.C•TuE4,ThA1
Zhang,Xiang•WH4
Zhang,Xiansheng•TuK40
Zhang,Xiaofan•TuK2
Zhang,Xiaoli•TuK19
Zhang,Xinhai•TuK19
Zhang,Xuejin•WI11
Zhang,Xueqian•ThC3,WF5,TuI4
Zhang,Y•WI37,WI39,TuE4,WG3
Zhang,Yan•ThD3,ThC4,TuK20
Zhang,Ye•WB4
74
Zhang,Yinfu•TuK2
Zhang,Ying•TuI4
Zhang,Yizhu•WG4
Zhang,Yuan•WI14
Zhang,Z•WI43
Zhang,Zeyu•ThB5
Zhang,Zhelin•TuE5
Zhang,Zhen•TuE5
Zhang,Ziyue• WI46
Zhang,Zongzhi•WG5,TuH3,TuK11
Zhao,Huan•ThC4,ThD3
Zhao,J•WI43
Zhao,Jie•WB3
Zhao,Jing•TuK7,WD3
Zhao,Kejia•WI31
Zhao,Kun•TuG4 ,WI38
Zhao,Lei•WD2
Zhao,Litao•ThB5
Zhao,Qiyi•WI13,WF4
Zhao,Wanying•TuH3,TuK9,TuK18
Zhao,Weisheng•TuK24
Zhao,Xiaoli•WI30
Zhao,Xin•WC1
Zhao,Yaping•WI23,WI26
Zhao,Zengxiu•WH3,TuK1,TuK7,TuK12,TuK14,TuK
22,WD3,WI42,WI43
Zheng Li•WF6
Zheng Zheng•WC1
Zheng,Shuiqin•TuB2
Zheng,Zhu•WI18
Zhong,J.Q. •ThB4
Zhong,Xiangli•WI14
Zhou,C. •WC4
Zhou,K. •TuK29
Zhou,Kui•ThB1
Zhou,L. •WC4
Zhou,Siyan•TuK37,WG6
Zhou,T. •TuK29
Zhou,Y. •WH1
Zhou,Yueming•WD5
Zhu,Jiangfeng•TuG1,TuG4
Zhu,Jianyu•WI30
Zhu,Liguo•TuF4
Zhu,Lipeng•WI13,WF4
Zhu,Weihua•WG5
Zhu,Xiaosong•TuK2
Zhu,Y. •ThC2
Zhu,Yiming•WI16
Zhu,Zhihong•TuK31
Zhuang,Naifeng•TuK11
Zhvanya,Irina A.•WG1
Zou,D. B. •TuG3
Zou,Pu•WB5
Zou,Ruijiao•TuK21
Zou,Yi•TuF4
75
SPONSORS
ANNOUNCEMENT
Welcome to Chengdu, China in 2020
to attend the 10th
International Symposium on Ultrafast Phenomena and Terahertz Waves
General Chair: Zeren Li
Co-chairs: Xi-Cheng Zhang, Ruxin Li
Organizing Chair: Liguo Zhu
Local Organizer: China Academy of Engineering Physics
There’re panda and Sanxingdui (c. 1,600 BCE) archaeological site too!
Detailed information will be announced soon.
Contact for more information: Prof. Liguo Zhu
技科 大防 学
国
Website and Wechat public account: