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[IMLB 2012] 제 16차 IMLB 국제학술대회 (IMLB 2012) 대회 사전등록 안내
제16차 IMLB 국제학술대회 (IMLB 2012) 소개
- 사전등록 마감: 2012년 5월 15일 -
제16차 IMLB 국제학술대회(IMLB 2012)가 2012년 6월 17일(일)부터 22일(금)까지 일주일 간 제주국제컨벤션센터에서 한국전기화학회와 한국전지산업협회 공동 주최로 개최됩니다. IMLB 는 매 2년 마다 대륙간을 이동하면서 개최되는 리튬이차전지 등 에너지 저장장치 분야에서 최고 권위를 자랑하는 세계대회이며, 이번 대회는 한국에서 최초로 개최되는 IMLB 대회입니다. .
“New Era for Smart Energy Storage”라는 주제 하에 개최되는 제 16차 IMLB 국제학술대회는 최근 신성장동력 산업으로 주목 받고 있는 리튬전지를 주제로, 약 50개국 2,000여명의 관련 산업 종사자 및 연구자들이 한데 모여 최신 기술을 공유하고 새로운 트렌드를 만들어내는 장입니다. IMLB 2012 조직위원회는 관련 분야의 최고 석학들을 초청연사로 모셔 학술 프로그램을 구성하였으며, 최신 기술을 한 자리에서 만나볼 수 있는 전시 프로그램과 관련 분야의 최신 기술을 직접 체험할 수 있는 제주스마트그리드홍보관 및 제주의 아름다운 관광지로 구성된 테크니컬 투어를 준비 중입니다.
제16차 IMLB 국제학술대회의 사전 등록은 5월 15일까지 진행되며, 학술대회 프로그램 및 등록에 관련된 사항은 홈페이지(http://www.imlb2012.org)에 보다 상세하게 안내되어 있습니다. 관련 산업 종사자 및 연구자 여러분들의 많은 관심과 적극적인 참여를 부탁 드립니다.
[등록비 및 사전행사 안내]
구분 |
카테고리 |
사전등록 (5월 15일 까지) |
현장등록 (5월 16일부터) |
등록비 |
일반 |
600,000원 |
700,000원 |
학생 |
300,000원 |
350,000원 | |
동반자 |
150,000원 |
200,000원 | |
*동반자 등록은 참가자의 배우자나 가족의 경우에만 적용 가능합니다. (학술장 출입 불가) | |||
사교행사비 |
Welcome Reception |
무료 | |
Welcome Dinner |
10,000원 | ||
Technical Tour |
20,000원 | ||
Banquet |
80,000원 |
[Topic]
Cathode materials Electrolytes and separators Modeling and analysis Cell design and evaluation Supercapacitors |
Anode materials Interface phenomena Safety and reliability System and application New battery systems |
- 초청연사 리스트
*국내초청연사는 곧 추가로 확정, 공지될 예정입니다.
No. |
Name |
Affiliation |
Country |
Title |
1 |
Takeshi Abe |
Kyoto University |
Japan |
Electrochemical Properties of Graphite in Propylene Carbonate-based Electrolytes |
2 |
Khalil Amine |
Argonne National Laboratory |
USA |
Advanced Composite Cathode and Graphene/Silicon Anode as High Energy System for Automotive Applications |
3 |
Michel Armand |
CIC Energigune |
Spain |
Will Safety Concerns Change our Electrolytes? Back to Solid-State? |
4 |
Doron Aurbach |
Bar-Ilan University |
Israel |
Rechargeable Lithiated Silicon-Sulfur (SLS) Battery Prototypes |
5 |
Mahalingam Balasubramanian |
Argonne National Laboratory |
USA |
Battery Science Using Hard X-ray Core-Shell Spectroscopic Methods at Sector-20 Beamlines at the Advanced Photon Source |
6 |
Brian M.Barnett |
TIAX LLC |
USA |
Lithium-Ion Battery Safety: Mechanisms of Safety, Predictions of Impending Thermal Runaway and Integrity of Safety Testing |
7 |
Kirill G. Bramnik |
BASF |
Germany |
Improved Cathode Materials and Electrolytes as Key Ingredients of Next Generation Lithium Ion Batteries |
8 |
Ralph J. Brodd |
Broddarp of Nevada, Inc. |
USA |
Costs of Li-Ion Batteries for Automotive Applications |
9 |
Peter G. Bruce |
University of St. Andrews |
UK |
Positive Aspects of the Non-aqueous Li-O2 Battery |
10 |
Gerbrand Ceder |
Massachusetts Institute of Technology |
USA |
The Limits of Li, Na and Mg Intercalation |
11 |
Yet-Ming Chiang |
Massachusetts Institute of Technology |
USA |
Lithium Ion Flow Batteries for Large Scale Energy Storage |
12 |
Yi Cui |
Stanford University |
USA |
High Energy Battery Electrodes: Silicon Anodes and Sulfur Cathodes |
13 |
Jeff Dahn |
Dalhousie University |
Canada |
Do Short-Term Precision Measurements Mirror Long-Term Cycle Life? |
14 |
Claude Delmas |
Université Bordeaux |
France |
The Electrochemical Processes Involved during Cycling of Overlithiated Li(Li,Mn,Co,Ni)O2 Layered Oxides |
15 |
Vincent Giordani |
Liox Power, Inc. |
USA |
Freely Diffusing Oxygen Evolving Catalysts for Rechargeable Li-O2 Batteries |
16 |
Clare P. Grey |
Stony Brook University & University of Cambridge |
UK |
Following Function in Real Time: New NMR and MRI Methods for Studying Structure and Dynamics in Batteries and Supercapacitors |
17 |
David Howell |
U.S. Department of Energy |
USA |
Fiscal Year 2012 Highlights of Automotive Energy Storage R&D Funded by the U.S. Department of Energy |
18 |
Chi-Chang Hu |
National Tsing Hua University |
Taiwan |
Anodic Deposition of Nano-structured Mn Oxides for Supercapacitors: Nanostructure Design and Electrochemical Quartz Crystal Microbalance Study |
19 |
Xuejie Huang |
Institute of Physics, Chinese Academy of Sciences |
China |
Silicon Thin Film Anode for Li-ion Batteries |
20 |
Patrik Johansson |
Chalmers University of Technology |
Sweden |
New Electrolyte Material Strategies for Old and New Battery Concepts |
21 |
Kiyoshi Kanamura |
Tokyo Metropolitan University |
Japan |
Development of Rechargeable Lithium-Metal Battery by using 3DOM Polyimide Separator |
22 |
Ryoji Kanno |
Tokyo Institute of Technology |
Japan |
Lithium Superionic Conductor, Li10GeP2S12, and its Application to All Solid-state Batteries |
23 |
Tomohiro Kawai |
Mitsubishi Chemical Corporation |
Japan |
Thermal Analysis for Safety of Electrolytes |
24 |
Tomohide Kazama |
Nomura Research Institute, Ltd. |
Japan |
Trends of Electrified Vehicles and Implications for the Battery Business |
25 |
Lingli Kong |
Tianjin Lishen battery Joint-Stock Co., Ltd. |
China |
The Improvement of High Temperature Performance of Li ion Battery with LMO or NCM by Using Blend of Salts or Additives in LiPF6 Based Electrolyte |
26 |
Robert Kostecki |
Lawrence Berkeley National Laboratory |
USA |
In situ Far- and Near-Field Diagnostics of Electrical Energy Storage Systems |
27 |
Sujeet Kumar |
Envia Systems Inc. |
USA |
High Energy Lithium ion Batteries based on Layered-Layered Cathode and Silicon Anode |
28 |
Xingjiang Liu |
Tianjin Instiute of Power Sources |
China |
Control of Interface of Glass-ceramic LATP/Liquid Electrolyte for Aqueous Lithium Batteries |
29 |
Douglas R.MacFarlane |
Monash University |
Australia |
Organic Ionic Plastic Crystal Electrolytes for Lithium (Metal) Batteries |
30 |
Joachim Maier |
Max Planck Institute for Solid State Research |
Germany |
Thermodynamics of Lithium Storage |
31 |
Arumugam Manthiram |
University of Texas at Austin |
USA |
Understanding the Intricacies of High-voltage Spinel Cathodes |
32 |
Christian Masquelier |
Université de Picardie Jules Verne Amiens |
France |
Investigation of Li+ Insertion/Extraction Mechanisms in Positive Electrodes for Li Batteries: Phosphates, Fluorophosphates and Silicates |
33 |
MarkMathias |
General Motors |
USA |
Reaching the Automotive Advanced Lithium-Ion Battery Frontier |
34 |
KatsuhikoNaoi |
Tokyo University of Agriculture & Technology |
Japan |
“Nanohybrid Supercapacitor” Utilizing Hyper-Dispersed nc-Li4Ti5O12 Composited with SGCNT |
35 |
Linda F.Nazar |
University of Waterloo |
Canada |
Graphene-Metal Oxide Catalysts for Li-O2 Batteries |
36 |
Hiroyuki Nishide |
Waseda University |
Japan |
Radical Polymers as a Cathode Active Material of Lithium Ion Batteries |
37 |
Petr Novák |
Paul Scherrer Institute |
Switzerland |
Elucidating the Reaction Mechanism of M0.5TiOPO4 Electrode Materials |
38 |
Zempachi Ogumi |
Kyoto University |
Japan |
Advanced Analysis Technology for Understanding Battery Reactions |
39 |
TetsuyaOsaka |
Waseda University |
Japan |
Highly Durable Si Anode More than Several Thousand Cycles and its Properties |
40 |
EmanuelPeled |
Tel Aviv University |
Israel |
Challenges and Obstacles in the Development of Sodium-Air Batteries |
41 |
BrunoScrosati |
Sapienza Università di Roma |
Italy |
Progresses in Lithium Ion Batteries |
42 |
Norio Takami |
Toshiba Corporation |
Japan |
High-Power and Long-Life Li-Ion Batteries Using Lithium Titanium Oxide Anode for Automotive and Stationary Power Applications |
43 |
Jean-MarieTarascon |
Université de Picardie Jules Verne |
France |
F-based Sulphates Frameworks and their Use in Li-ion Batteries |
44 |
KuniakiTatsumi |
National Institute of Advanced Industrial Science and Technology |
Japan |
Study on Surface Modifications of Positive Electrode Materials |
45 |
Cecile Tessier |
SAFT |
France |
High Energy Cells and Ageing Mechanisms |
46 |
Michael M. Thackeray |
Argonne National Laboratory |
USA |
High Capacity Li- and Mn-rich Metal Oxide Electrodes: Challenges and Opportunities |
47 |
Josh Thomas |
Uppsala University |
Sweden |
Cell-Chemistry and the EV BMS Algorithm |
48 |
Steven Visco |
PolyPlus Battery Company Inc. |
USA |
Next Generation Li-Air and Li-S Batteries based on Ceramic Protected Li Electrodes |
49 |
Gordon Wallace |
University of Wollongong |
Australia |
Flexible, Wearable Electrodes based on Carbon Nanotubes and/or Graphene for Capacitor Applications |
50 |
Masayoshi Watanabe |
Yokohama National University |
Japan |
A New Family of Ionic Liquids for Advanced Lithium Secondary Batteries |
51 |
Martin Winter |
University of Muenster |
Germany |
“Communication” between Anode and Cathode and their Influence on Performance in Lithium Ion Batteries |
52 |
Margret Wohlfahrt-Mehrens |
Zentrum für Sonnenenergie- und Wasserstoff-Forschung |
Germany |
Influence of Partial Substitution on Lithium Manganese and Lithium Cobalt Phosphate |
53 |
Yongyao Xia |
Fudan University |
China |
High Energy Density Hybrid Supercapacitor Using Mesoporous Carbon and Ti-based Material |
54 |
Kang Xu |
U.S. Army Research Laboratory |
USA |
Electrolyte/Electrode Interphases in Li Ion Batteries |
55 |
Atsuo Yamada |
The University of Tokyo |
Japan |
High-Voltage Pyrophosphate Cathode |
56 |
Jun-ichi Yamaki |
Kyushu University |
Japan |
Influence of LiPF6 on the Thermal Stability of Graphite with Electrolyte |
57 |
Yong Yang |
Xiamen University |
China |
The Studies of Silicates an Fluorophosphates as High Capacity Cathode Materials for Li-ion Batteries |
58 |
Xiao-Qing Yang |
Brookhaven National Laboratory |
USA |
Structural Changes of Cathode Materials for Lithium-ion Batteries during Heating Studied by the Combined in situ XRD, X-ray Absorption and TEM |
59 |
Rachid Yazami |
Nanyang Technological University |
Singapore |
Thermodynamics Spectrometry; A New Investigation Tool For Electrode Materials And Batteries: A Review |
60 |
Gleb Yushin |
Georgia Institute of Technology |
USA |
Nano-Composite Anodes for Use in Li-ion Batteries with Enhanced Performance |
61 |
Karim Zaghib |
Hydro-Québec |
Canada |
Lithium Metal and Li-ion Batteries for Transportation and Energy Storage: Challenges and Opportunities |
62 |
Ji-Guang Zhang |
Pacific Northwest National Laboratory |
USA |
Effects of Graphene Based Air Electrode and Nonaqueous Electrolytes on the Performance of Li-Air Batteries |
63 |
John Zhang |
Celgard, LLC |
USA |
Li-ion Design and Li-ion Safety |
*IMLB 2012 Newsletter를 받아보시려면 www.imlb2012.org에서 sign up 바랍니다.