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 |
