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March, 1973 March, 1975 August, 1979
May, 1981 November, 1989 April, 1997 April, 2006 October, 2011 October, 2012
Yoshinao Mishima
Affiliation Tokyo Institute of Technology
Research Area Structural Materials, Heat resistant Materials, Thermoelectric Materials
Academic Career
Profile
Professional Experience
Title President
E-mail [email protected]
Web Site http://www.titech.ac.jp/english/about/president/index.html
B.S. from Tokyo Institute of Technology, Department of Metallurgical EngineeringM.S. from Tokyo Institute of Technology, Department of Metallurgical EngineeringPh.D from the University of California, Berkeley, Department of Materials Science andEngineering
Professional CareerAssociate, Precision and Intelligence Laboratory, Tokyo Institute of TechnologyAssociate Professor, Precision and Intelligence Laboratory, Tokyo Institute of TechnologyProfessor, Department of Materials Science and Engineering, Tokyo Institute of TechnologyDean, Interdisciplinary Graduate School of Science and Engineering,Tokyo Institute of TechnologyExecutive Vice President, Tokyo Institute of Technology (2011-2012)President, Tokyo Institute of Technology
March, 1970 March, 1972 March, 1981
March, 1974 May, 1977
April, 1981 October, 1988
October, 1994 July, 1998
October, 1998
April, 2001
April, 2005 April, 2011 October, 2012
E-mail [email protected] , [email protected]
Bachelor of Engineering, University of TokyoMaster of Engineering, University of TokyoPh.D from University of Tokyo
Professional CareerResearch Assistant, Engineering Research Institute, School of Engineering, University of TokyoAssistant Professor, Department of Synthetic Chemistry, School of Engineering,University of TokyoResearch Associate, Department of Chemistry, School of Science, Texas A&M UniversityAssociate Professor, Department of Synthetic Chemistry, School of Engineering,University of TokyoAssociate Professor, Engineering Research Institute, School of Engineering, University of TokyoAssociate Professor, Department of Applied Chemistry, Graduate School of Engineering,University of TokyoProfessor, Division of Materials Science & Chemical Engineering,Faculty of Engineering, Yokohama National UniversityProfessor, Division of Materials Science & Chemical Engineering, Graduate School ofEngineering, Yokohama National UniversityProfessor, Chemical Resources Laboratory, Tokyo Institute of TechnologyDirector, Chemical Resources Laboratory, Tokyo Institute of TechnologyExecutive Vice President for Research, Tokyo Institute of Technology
Takashi Tatsumi
Affiliation Tokyo Institute of Technology
Research Area Synthesis and Catalytic Applications of Novel Zeolites and Mesoporous Materials Design of Catalytic Reactions toward Green Chemical Synthesis
Academic Career
Profile
Professional Experience
Title Executive Vice President for Research
September, 1970
April, 1971 March, 1986 March, 1993 March, 1998 March, 2002 March, 2005
March, 2006 March, 2008 October, 2008 September, 2009 April, 2011 October, 2012
E-mail [email protected], [email protected]
Bachelor of Arts in Law, University of Tokyo
Professional CareerJournalist, Nihon Keizai Shimbun (Nikkei Inc.)Bureau Chief (Houston, Texas), Nikkei Inc.Editor-in-Chief, Nikkei Business, Nikkei BP Inc.Deputy Director, President's Office, Nikkei Inc.Managing Director and Publisher, Nikkei Business, Nikkei BP Inc.Senior Operating Officer, Corporate Strategy Development, University-Industry Relations &Group Publisher of Nikkei BizTech, Nikkei BP Inc.Managing Director, Nikkei BP Inc.Corporate Auditor & Chairman of the Corporate Auditor's Board, Nikkei BP Inc.Professor, Graduate School of Science and Engineering, Tokyo Institute of TechnologyDirector, Institute of Corporate Governance JapanCorporate Auditor, Osaka Titanium Technologies, Inc.Executive Vice President for Finance and Public Relations, Tokyo Institute of Technology
Kiyoshi Otani
Affiliation Tokyo Institute of Technology
Academic Career
Profile
Professional Experience
Title Executive Vice President for Finance and Public Relations
Abstract We have been continuing exploration of new electro-active functionalities in transparent oxide-basedmaterials since 1994. If electro-active function could be imparted to abundant metal oxides, one wouldbe able to expect to have new material frontier for sustainable society. This expectation made me startthe explorative research on functional transparent oxides. As a result, application of oxide (IGZO)-thinfilm transistors to displays of iPad, smart phones and OLED-TVs started from 2012. In this talk Ireview our research on new material frontiers (Fig.1), focusing on iron-based superconductors whichwe discovered and electronic functionalities of a cement constituent 12CaO•7Al2O3..
Fig.1. High lights in our materials research
Hideo Hosono
Affiliation Frontier Research Center & Materials and Structures Laboratory
Research Area Materials Science 1. Iron-based Superconductors 2. Electro-Active Function utilizing abundant elements
Lecture
Title Discovery of Iron-based Superconductors and Creation of RT-stable Electride
Profile
Professional Experience
E-mail [email protected]
Web Site http://www.msl.titech.ac.jp/~hosono/
Title Professor
He received his Ph.D at 1982 in Applied Chemistry from Tokyo Metropolitan University and became a professor atMaterials and Structures Laboratory (MSL), Tokyo Institute of Technology in 1999 via associate professors of NagoyaInstitute of Technology, National Institute for Molecular Science and Tokyo Tech. In 2004. he moved to Frontier ResearchCenter, Tokyo Tech, and was appointed to the founding director of Materials Research Center for Element Strategy onAugust 1, 2012. He is a member of Science Council of Japan.
Masako Ikegami
Affiliation Graduate School of Decision Science & Technology, Department of Value and Decision Science
Lecture
Abstract Recent studies show that natural resources and wars/armed conflicts are highly correlated; for examplethe unusually high rate of civil wars in Sub-Saharan Africa, a region with many resource-dependentstates (Ross 2003, 2004). International security expert Michael T. Klare in Resource Wars (2002)argues that major wars over oil have been fought every decade or so since World War I, and assertsthat, as armies throughout the world define resource security as a primary objective, widespreadinstability is bound to follow, especially in those areas where competition for essential materialsoverlaps with long-standing territorial and religious disputes. Le Billon proposes political ecology ofwar based on the socially constructed nature of resources; the political economy, materiality andgeography of resources can significantly influence the likelihood and course of armed conflicts, whilethe needs and practices of war have influenced the pattern of resource exploitation and the state of theenvironment (Le Billon 2001: 566). Le Billon asserts that armed conflicts and natural resources can bedirectly related in two main ways: armed conflicts motivated by the control of resources, and resourcesintegrated into the financing of armed conflicts (op.cit.: 580). Nonetheless, such studies draw theirconclusions on limited observations on conflict-intensive regions like Africa and the Middle East. As aresult, their findings are usually less relevant to the cases where several major powers are involved,specifically in the East- and South China Sea in recent years. Against this background, my study willfocus on the contemporary maritime disputes and potential crisis in the East- and South China Sea overexplorable offshore gas fields. Using the lateral pressure theory (Choucri, North and Yamakage, 1992)as a benchmark model, this preliminary study aims to develop a system dynamic model to explain theempirical relationship between natural resources competition and the risk of armed conflict. In suchcontext, an interdisciplinary methodology combining global energy system analysis and energy securityis applicable.
Title Geopolitics of global energy and security
Profile
Professional Experience
E-mail [email protected] Site http://www.valdes.titech.ac.jp/organize/org-kettei.html#p6179
Title Professor
Research Area • Decision-making in the nuclear era: diplomatic historical perspectives • Arms control & nuclear disarmament, WMD non-proliferation • Nuclear deterrence & strategy: post-modern approaches • Regional security & CBMs for conflict prevention in the light of the European confidence building during the Cold War • Geo-politics, security, political economy & policy analysis of defence industry/technology R&D, global transfer of advanced dual-use technology, energy and resources • The US-Japan alliance, US/NATO security strategy • Regional conflict, reconciliation & peace-building • Crisis management & human security: European lessons & Asian facts
Dr. Masako Ikegami is Professor of Department of Value & Decision Science at Graduate School of Decision Science &Technology, Tokyo Institute of Technology since October 2013. Formerly she was a professor of political science (2010-13)and Director (2001-08) of the Center for Pacific Asia Studies at Stockholm University. She holds Doctor of Sociology(University of Tokyo, 1996) and Ph.D. in peace and conflict research (Uppsala University 1998). She gave lectures ateminent institutions in US, Europe and Asia. She held prestigious Abe Fellowship granted by the Social Science ResearchCouncil and Japan Foundation Center for Global Partnership for research on the paradox of extended nuclear deterrence inthe era of nuclear disarmament at East-West Center in Washington, D.C., Honolulu, and Senior Visiting Fellow at ResearchInstitute for Peace & Security in Tokyo. In 2005, she was POSCO Fellow at EWC, Honolulu to conduct research on NorthKorean nuclear crisis. She is a regular member of the Pugwash Conferences on Science and World Affairs (Nobel PeacePrize 1995) on arms control & nuclear disarmament, and a standing board member of the Swedish Pugwash Group chairedby Amb. Rolf Ekéus.
1980
2001 - Present 1989 - 2001 1980 - 1989
Ryoji Kanno
Abstract All solid-state batteries are promising candidate for the future energy storage systems with high energyand power densities. The most important issue to be solved is the materials for the solid electrolyte.Lithium superionic conductors promise the potential to replace organic liquid electrolytes and therebyimprove safety of the next-generation high-energy batteries. The Li10GeP2S12 (LGPS) has anextremely high ionic conductivity of over 10・2 S cm・1 at room temperature and its value is comparableto that of liquid systems. The LGPS has a three-dimensional framework structure, which provides a one-dimensional lithium conduction pathway. The composition change in the solid solution affects theconductivity. The structure analysis provided information of the conduction mechanism. The materialsvariety produced by the cationic and anionic substitution is important for the future practicalapplications. The LGPS phases were examined as a solid electrolyte and the battery characteristics weredemonstrated.
Title Lithium Superionic Conductor and Application to All Solid-state Battery
Profile
Professional Experience
E-mail [email protected]
Web Site http://www.kanno.echem.titech.ac.jp/
Graduate from School of Science, Osaka University
Professional CareerProfessor, Department of Electronic Chemistry, Graduate School of Science and Engineering,Tokyo Institute of TechnologyAssociate Professor, Faculty of Science, Kobe UniversityAssistant Professor, Faculty of Engineering, Mie University
Title Professor
Affiliation Interdisciplinary Graduate School of Science and Engineering Electronic Chemistry
Research Area Solid State Chemistry, Electrochemistry
Academic Career
Lecture
Takao Kashiwagi
Affiliation Advanced Energy Systems for Sustainability (AES)
Research Area Energy - Environment Systems Energy System Analysis Refrigeration and Air Conditioning
Lecture
After obtained his Ph.D. while studying the effects of heat transfer of critical air flow, Prof. Kashiwagi had longengaged in teaching at his old university, Tokyo Institute of Technology, and others. As the AES CenterDirector, he is leading its works with major companies involved in the energy sector to perform empiricalstudies and develop fundamental technologies that enable next-generation energy power generation. His serviceto numerous Government committees includes, Chairman, New Energy Subcommittee of the Ministry ofEconomy Trade and Industries, Japan (METI), Chairman, Advisory and Assessment Committee for Fuel Cell atthe Japanese Government Cabinet Office, and Member of the Science and Technology Expert Committee.
Abstract On April 11, 2014, the Cabinet decided to approve the new Strategic Energy Plan as the basis for theorientation of Japan’s new energy policy, considering the dramatic changes in energy environmentsinside and outside Japan.There are three key points in the amendments: 1; to clearly define a position for each source of energy 2; the addition of international and economic growth perspectives to the basicperspectives of energy policy 3; regulatory reform.Regulatory reform is crucial to economic growth. Indeed, the two are equivalent.
Title New Energy Policy in Japan and Open innovation Activity in Tokyo Tech
Profile
Professional Experience
E-mail [email protected]
Web Site http://aes.ssr.titech.ac.jp/english
Title Distinguished Professor / Center Director, AES
1980 1976 1974 – 1975
1996 – Present 1988 – 1996 2006 – Present 2006 – Present 2000 – 2005 1985 – 1986
Abstract For achieve sustainable development, social development to meet the needs of the present withoutcompromising the ability of future generations to meet their own needs (Brundtland Report, 1987), weneed to tackle really complex and “messy” systems problems. These messy systems have propertiesthat none of their parts have and these properties are lost when the system is taken apart. Hence, tomanage the messy problems, we definitely need to develop methodologies to understand the problemsituation as a system of interconnected, interdependent, and interacting problems. Social SystemicDesign Approach/Thinking is well known as one of such methodologies. Social Systemic Design Approach/Thinking is a collaborative, human-centered approach to solvingmessy problems by going through specific stages: (1) Understanding human needs (empathize), (2)framing the problem (define), (3) Generating ideas (ideate) and building models (prototype), and (4)Getting feedback to refine models (test). In this lecture, we focus on the ideate/prototype stage and claim social simulation approach ispromising and effective in this stage. Social simulation is necessary because the interactions ofadaptive agents typically lead to nonlinear effects that in particular are not amenable to the deductivetools of formal mathematics. Then, we illustrate the approach by taking as an example a trade-off problem of car sharing and socialsustainability. By using social simulation approach we try to answer the following research questions:(1) Under what conditions car sharing is getting popular and widespread, and (2) How compatible carsharing system and economic sustainability is. Finally, we refer to an essential role of Social Systemic Design Approach/Thinking in ourcollaboration scheme with FuturICT project conducted by EU.
Title Designing Social Systems toward a Sustainable World
Profile
Professional Experience
E-mail [email protected]
Web Site http://www.valdes.titech.ac.jp/~kk-lab/overview/kijima.html
Doctor of Engineering in Industrial Engineering and Management, Tokyo Institute of TechnologyMaster of Engineering in Industrial Engineering and Management, Tokyo Institute of TechnologyResearch Student, Dept. of Mechanical Engineering, Melbourne University, Australia
Professional CareerProfessor of Decision Systems Sciences, Dept. of Value and Decision Science,Tokyo Institute of TechnologyAssociate Professor, Dept. of Industrial Engineering and Management, Tokyo Institute of TechnologyVisiting Professor, Hull University Business School, UKVisiting Professor, School of Business Management, Bandung Institute of Technology, IndonesiaVisiting Professor, University of TokyoHonorary Visiting Research Fellow, Dept. of Systems, University of Lancaster, UK
Title Professor
Kyoichi Kijima
Affiliation Graduate School of Decision Science and Technology Value and Decision ScienceResearch Area Systems Sciences; in particular, Applied Systems Thinking, Decision Systems Science, Service Systems Science, Systems Management, General Systems Theory
Academic Career
Lecture
1985
1984 1994 2006
Takehiko Mori
Affiliation Graduate School of Science and Engineering Department of Organic and Polymeric MaterialsResearch Area Solid State Chemistry, Organic Electronics, Organic Conductors
Academic Career
Lecture
Abstract Organic electronic and photonic devices are attracting a great deal of attention due to the potentialapplication to large-area, low-cost, and flexible electronic devices. We have explored new organicsemiconductors for organic transistors, among which particular attention has been recently paid toambipolar semiconductors, where both electron and hole transport is possible. Ambipolarsemiconductors are important not only for transistors but also for solar cells. We have founddiphenylindigo (Figure) shows excellent ambipolar transistor properties. Indigo is a dye known fromthe ancient time, and is popularly used in blue jeans. The characteristic blue color is associated withthe long-wavelength absorption, and the resulting small HOMO-LUMO gap is crucial to realize theambipolar transport. We discuss why this compound shows excellent performance from the structuralpoint of view, and how the two kinds of charge carriers are transported in the actual transistors.
Title Recent Advances in Organic Transistor Materials
Profile
Professional Experience
E-mail [email protected]
Web Site http://www.eng.titech.ac.jp/index_e.html http://www.op.titech.ac.jp/lab/mori/index.e.html
PhD, The University of Tokyo, Department of Chemistry
Professional CareerResearch Associate, Institute for Molecular ScienceAssociate Professor, Tokyo Institute of TechnologyProfessor, Tokyo Institute of Technology
Title Professor
NH
OHN
O
April, 2014 March, 2012 April, 2009 September, 1994 April, 1994
April, 1981 March, 1981
Atsushi Morihara
Affiliation Tokyo Institute of Technology Solution Research Laboratory / Mitsubishi Corporation
Research Area Renewable Energy Coal Gasification Fuel Cell Hydrogen Energy
Lecture
Abstract In order to address the serious challenge of green house effect, renewable energies such as photovoltaicenergy, wind power and geothermal energy have been already developed globally. Equally, marineenergy technology also carries a critical importance in the renewable energy as the majority of (90%) ofthe earth surface is taken up by the sea. In my presentation, Japan’s latest marine renewable strategies will be discussed. Further, I will discuss the hydrogen technologies as one of the alternative technologies for importingenergy source. Japan is aiming at establishing a hydrogen society where we generate energy throughrenewable energy source outside of Japan, covert it to hydrogen for an effective energy import.
Title Renewable Energy Technologies for Marine Energy Sources and Hydrogen as a Future Energy Carrier
Profile
Professional Experience
E-mail [email protected]
Web SiteSolution Research laboratory http://www.ssr.titech.ac.jp/english/index.htmlInternational Research Center of Advanced Energy Dydtems for Sustainability http://aes.ssr.titech.ac.jp/english
Group Chief Technology Officer, Mitsubishi Corporation (Japan)Professor Ph.D., Tokyo Institute of Technology (Japan)General Manager, Mitsubishi Corporation (Japan)Visiting Researcher, Massachusetts Institute of Technology (US)Doctor of Philosophy, Tohoku University (Japan) “Integrated Coal Gasification CombinedCycle”Researcher, Hitachi Research Laboratory, Hitachi Ltd. (Japan)Bachelor of Chemical Engineering, University of Tokyo (Japan)
Title Professor / Group Chief Technology Officer
1993 1995 1999
1995 – 1996 1996 – 2007 2000 – 2001 2007 – 2012 2012 – present
Shuichi Murakami
Abstract One of the recent hot topics in condensed matter physics is various topological phases realized inmaterials. They include quantum Hall systems, which were experimentally found in 1980, andtopological insulators, which were theoretically proposed in 2005 and experimentally confirmed in2007. In these systems, the interior is insulating and not conducting electric current, whereas thesystem boundaries (edges or surfaces) are metallic. This property persists even if the material is cutinto two; the section then immediately becomes a surface, and it becomes metallic. This novel propertyis attributed to a topological order in the material. It is interesting that such an abstract mathematicalconcept is hidden in real materials. In my presentation, I explain these concepts for electrons in real materials. Recently we are alsoextending such a concept into other particles in condensed materials. The particles to be studiedinclude photons (light) and magnons (spin waves) in magnets. In my talk we also explain thesetheories, and show how the concept of topological order is universally found in various particles incondensed materials.
Title Topological Phases in Condensed Matter
Profile
Professional Experience
E-mail [email protected] Site http://www.phys.titech.ac.jp/ http://www.stat.phys.titech.ac.jp/murakami/etop.html
B.S.: University of TokyoM. S.: University of TokyoPh. D., University of Tokyo
Professional CareerJSPS Research Fellowship for Young Scientists(DC1)Assistant Professor, University of TokyoVisiting Scientist, Stanford UniversityAssistant Professor, Tokyo Institute of TechnologyProfessor, Tokyo Institute of Technology
Title ProfessorAffiliation Graduate School of Science and Engineering Physics (Condensed Matter Physics)Research Area My research area is theoretical condensed matter physics. In particular, Myresearch interest is on spin transport phenomena in solids, such as spin Hall effectin semiconductors and metals. It also includes topological insulators and theirnovel physical phenomena. My research is not limited to electronic phenomena,but I am also interested in various topological phenomena caused by geometricphases in various kinds of particles in solids, such as photons, magnons, andplasmons.
Academic Career
Lecture
1967 1969 1974 2013
1963-1967 1967-1972
1972-1974 1974-1977 1977-1986
1986-1988 1988-1996 1996-2009
2009-
Yoshinori Ohsumi
Affiliation Frontier Research Center, TITECH
Research Area Molecular Cell Biology
Academic Career
Lecture
Abstract Autophagy is a bulk protein degradation system well conserved from yeast to higher eukaryotes.Recently it is getting clear that autophagy is relevant to so many physiological events and diseases.More than 26 years ago we first found autophagy induced by nutrient starvations in the yeast, S.cerevisiae, under a light microscope. Taking this advantage of the yeast, we succeeded in isolation ofmany autophagy-defective mutants. We know now that 18 ATG genes are essential for starvation-induced autophagy. These Atg proteins function concertedly in the sequestration of cytoplasmicconstituents, the formation of a specialized membrane, known as the autophagosome. The Atg proteinsconsist of six functional units, namely the Atg1 protein kinase and its regulators, the PI3 kinasecomplex, the Atg2-Atg18 complex, the membrane protein Atg9, and two unique ubiquitin-likeconjugation systems. Since these ATG genes are well conserved from yeast to mammals and plants, avast range of studies in autophagy have recently been undertaken in various organisms. These proteinsfunction spatiotemporally in a concerted manner on the peri-vacuolar structure named the PAS.Present our knowledge on dynamic functions of Atg proteins during autophagosome formation andrecent physiological studies of autophagy in yeast will be discussed.
Title Looking Back on 26 Years of Autophagy Research
Profile
Professional Experience
E-mail [email protected]
Web Site http://www.ohsumilab.aro.iri.titech.ac.jp/
The University of Tokyo, College of Arts and Sciences, B. Sc.The University of Tokyo, Graduate School of Sciences, M.Sc.The University of Tokyo, Graduate School of Sciences, D.Sc.EMBO Member
Professional CareerUndergraduate Student, College of Arts and Sciences, The University of TokyoGraduate Student, Department of Biochemistry, College of Arts and Sciences, The University of Tokyo,with Prof. Kazutomo ImahoriResearch Fellow, Department of Agricultural Chemistry, Faculty of Agriculture, The University of TokyoPost Doctoral Fellow, Rockefeller University with Prof. Gerald M. EdelmanResearch Associate, Department of Biology, Faculty of Science, The University of Tokyo, with Prof.Yasuhiro AnrakuLecturer, Department of Biology, Faculty of Science, The University of TokyoAssociate Professor, Department of Biology, College of Arts and Sciences, The University of TokyoProfessor, Department of Cell Biology, National Institute for Basic Biology, Okazaki Professor, TheGraduate University for Advanced StudiesAdvanced Research Organization, Frontier Research Center, Tokyo Institute of Technology
Title Honorary Professor
1989 1993
1993 – 1995 1995 – 2003 2003 – 2010 2010 – Present
Hideki Taguchi
Affiliation Graduate School of Bioscience and Biotechnology Biomolecular Engineering
Research Area Biochemistry, Protein science, Moleular chaperones, Yeast prions
Academic Career
Lecture
Abstract Life depends on the function of proteins. Proteins are linear chains of amino acids (polypeptide chains)that adopt unique three-dimensional structures. The polypetide chains must fold into the tertiarystructures for biological functions. Basically, the folding process is spontaneous. However, proteinfolding is often hampered by inter-molecular protein aggregation, which can be prevented by a variety ofchaperone proteins in the cell. In this talk, I would like to talk about our recent works on global analyseson aggregation and chaperone (1-3).
1. Niwa, T. et al., Bimodal protein solubility distribution revealed by an aggregation analysis of the entireensemble of Escherichia coli proteins. Proc. Natl. Acad. Sci. U.S.A. 106, 4201-4206 (2009)2. Niwa, T., et al. Global analysis of chaperone effects using a reconstituted cell-free translation system.Proc. Natl. Acad. Sci. U.S.A. 109, 8937-8942 (2012)3. Fujiwara, K. et al., A systematic survey of in vivo obligate chaperonin-dependent substrates. EMBO J.29, 1552-1564 (2010)
Title Ideal and reality in the protein world: protein aggregation and chaperone
Profile
Professional Experience
E-mail [email protected] Site http://www.bio.titech.ac.jp/english http://www.taguchi.bio.titech.ac.jp/eng
B.S. in Organic chemistry, Tokyo Institute of Technology, JapanPh.D. in Biochemistry, Tokyo Institute of Technology, Japan
Professional CareerPostdoctoral Fellow of Japan Society for the Promotion of Science (JSPS), Chemical ResourcesLaboratory, Tokyo Institute of TechnologyAssistant Professor, Chemical Resources Laboratory, Tokyo Institute of TechnologyAssociate Professor, Graduate School of Frontier Sciences, University of TokyoProfessor, Graduate School of Biosciences and Biotechnology, Tokyo Institute of Technology
Title Professor
1987
2010 ‐Present 2002 ‐2010 1996 ‐2002 1992 ‐1996 1987 ‐1992
Kenji Takeshita
Affiliation Research Laboratory for Nuclear Reactors
Research Area Nuclear Chemical Engineering, Nuclear Fuel Cycle, Waste Management, Environmental Chemistry, Separation Engineering
Academic Career
Lecture
Abstract A TPEN derivative with 4 vinyl groups, N,N,N',N' -tetrakis-(4-propenyloxy-2-pyridylmethyl)ethylenediamine (TPPEN) was synthesized for the separation of trivalent minor actinide(Am(III)) and lanthanide (Eu(III)). A copolymer gel with TPPEN and N -isopropylacrylamide (NIPA)showed a high separation factor of Am(III) over Eu(III) (SFAm/Eu), which was evaluated to be 26 at pH 5.Thin film of NIPA-TPPEN gel (average thickness: 2-40 nm) was immobilized on the pore surface inporous silica particles (particle diameter : 50μm, average pore diameter : 50 and 300 nm) and achromatographic column (diameter: 6mm, height: 11mm) packed with the gel-coated particles wasprepared. A small amount of weakly acidic solution (pH4) containing Am(III) and Eu(III) was suppliedin the column and the elution tests of Am(III) and Eu(III) were carried out. Eu(III) was recoveredseparately by a weakly acidic eluent (pH4) at 313K and Am(III) by a highly acidic eluent (pH2) at 298K.These results suggest that the contentious separation of MAs and Lns is attainable by a new extractionchromatographic process with two columns adjusted to 298K and 313K.
Title Extraction Chromatographic Separation of Minor Actinides and Lanthanides by TPEN-immobilized Gel
Profile
Professional Experience
E-mail [email protected] Site http://www.nr.titech.ac.jp/jp/index.html http://www.nr.titech.ac.jp/~takeshita/index-e.html
Doctor of Engineering, Nuclear Engineering, Tokyo Institute of Technology
Professional CareerProfessor, Res. Lab. for Nucl. Reactors, Tokyo Institute of TechnologyAssociate Professor, Chemical Resource Laboratory, Tokyo Institute of TechnologyAssociate Professor, Dept. of Env. Sci. Technol., Tokyo Institute of TechnologySenior Researcher, Institute of Research and InnovationResearcher, Institute of Research and Innovation
Title Professor