Co-Chairs: E.S. Takeuchi and E. Darcy
| Time | Abs# | Title | View |
|---|---|---|---|
| 10:40 | 61 | Improvement of High-Temperature Characteristics of Sintered Nickel Positive Electrode for Nickel-Metal Hydride@Battery - K. Shinyama, Y. Magari, T. Tanaka, Y. Harada, T. Nohma, and I. Yonezu (Sanyo Electric Co., Ltd.) | |
| 11:00 | 62 | Effects of Prolonged Milling and Carbon Contamination on the Characteristics of MgNi Alloy Used as Negative Electrode in Ni-MH Batteries - L. Roue, S. Ruggeri (INRS), G. Liang, J. Huot, and R. Schulz (Institut de Recherche d'Hydro-Quebec) | |
| 11:20 | 63 | Electrochemical Characteristics of Mg-based Alloy Prepared by HT and MG for Nickel-Metal Hydride Secondary Batteries - C. Wonsub, N. Byungwook (Pusan National University), and K. Ingon (Dongeui University) | |
| 11:40 | 64 | Structured Negative Electrodes for NiMH Cells - A.H. Whitehead, M. Harrer, and M. Schreiber (Funktionswerkstoffe F & E GmbH) |
Co-Chairs: R. Koetz and B.Y. Liaw
| Time | Abs# | Title | View |
|---|---|---|---|
| 2:00 | 65 | Effect of Cobalt on Physicochemical Properties of AB5 Type Metal Hydride Alloys - R. Ambrosio and E. Ticianelli (Instituto de Quimica de Sao Carlos - USP) | |
| 2:15 | 66 | A Differential Impedance Method for Investigation of Porous Lithium- and Metal Hydride - Battery Electrodes - P. Georen, A.-K. Hjelm, G. Lindbergh, and A. Lundqvist (The Royal Institute of Technology, KTH) | |
| 2:30 | 67 | In-Situ Electrochemical Analysis of Nickel-Metal Hydride Batteries under Fast Charging - X.-G. Yang, K. Bethune, and B.Y. Liaw (University of Hawaii) | |
| 2:45 | 68 | Temperature and Alkali Cation Dependency on the Memory Effect and Its Reconditioning Observed in Alkaline Secondary Batteries - Y. Sato, M. Morishita, and K. Kobayakawa (Kanagawa University) | |
| 3:00 | 69 | Influence of Electrode Composition on Cycling Performance of Cylindrical Nickel-Zinc Cells - W. Taucher-Mautner and K. Kordesch (Graz University of Technology) | |
| 3:15 | 70 | Preparation of Mn-Pb Mixed Oxide Electrode and its Discharge-Recharge Characteristics - K. Miyazaki, S. Kumamoto, and T. Kato (Fukuoka University) | |
| 3:30 | 71 | Modeling Rapid Charge Conditions in a VRLA Traction Battery - B.Y. Liaw, K.P. Bethune, and X.G. Yang (University of Hawaii at Manoa) | |
| 3:45 | 72 | Effect of Sn and Ca Doping on the Corrosion of Pb Anodes in Lead Acid Batteries - D. Slavkov, B. Haran, R. White, B. Popov (University of South Carolina), and F. Fleming (NorthStar Battery Company) | |
| 4:00 | Thirty-Minute Intermission | ||
| 4:30 | 73 | Fundamentals of Air - Metal Batteries with Polyaniline-based Catalysts - V. Barsukov, V. Khomenko, S. Chivikov (Kiev State University of Technologies & Design), and T. Motronyuk (National Technical University of Ukraine) | |
| 4:45 | 74 | Printed Air-Electrodes for Thin-Form Batteries - P. Atanassova, P. Atanassov, R. Bhatia, M. Hampden-Smith, T. Kodas, P. Napolitano (Superior MicroPowders), S. Gamburzev, K. Petrov, and A.J. Appleby (Texas A&M University) | |
| 5:00 | 75 | Electrochemical Characterization of Manganese Oxides Used in Air Electrodes - L. Mao (Matsushita Electric Industrial Co., Ltd.), D. Zhang (Tokyo Institute of Technology), K. Nakatsu, N. Koshiba (Matushita Battery Ind. Co. Ltd), T. Sotomura (Matsushita Electric Industrial Co., Ltd.), and T. Ohsaka (Tokyo Institute of Technology) | |
| 5:15 | 76 | More Specific Energy in Rechargeable Zn/Air Cells - F. Holzer and S. Müller (Paul Scherrer Institut) | |
| 5:30 | 77 | Current-Voltage Responses of Sugar-Air Cells with Ag Fuel Electrode in Alkaline Aqueous Solution - T. Sotomura (Matsushita Electric Ind. Co., Ltd.), T. Koga, and I. Taniguchi (Kumamoto University) | |
| 5:45 | 78 | A New Sugar-air Battery Using Electrocatalytic Oxidation of Sugars at Metal Electrodes - I. Taniguchi, T. Koga, M. Nakayama (Kumamoto University), and T. Sotomura (Matsushita Electric Ind. Co. Ltd.) |
Co-Chairs: B. Scrosati and C. Barbero
| Time | Abs# | Title | View |
|---|---|---|---|
| 8:30 | 79 | Supercapacitors for Peak-Power Application with a Fuel Cell System - R. Koetz, S. Mueller, M. Baertschi, B. Schnyder, P. Dietrich, and F. Buechi (Paul Scherrer Institut) | |
| 9:00 | 80 | Response of Hybrid Power Supplies Combining Ultracapacitors with Direct Methanol Fuel Cells - D. Tarnowski (T/J Technologies, Inc.), H. Lei (University of Michigan), C. Peiter, and M. Wixom (T/J Technologies, Inc.) | |
| 9:15 | 81 | High Power Double-Layer Capacitor Developments and Applications - V. Hermann, A. Schneuwly, and R. Gallay (Montena Components) | |
| 9:30 | 82 | Impact of the Basic Materials on the Performance of EDLCs for High Power - H. Michel, A. Schwake, and C. Weber (EPCOS AG Business Unit Ultracapacitors) | |
| 9:45 | 83 | Capacitance of Activated Carbon Cloth Electrodes in Aqueous Acidic Solutions - Y. Matsuda, R. Tsuda, and K. Hamada (Kansai University) | |
| 10:00 | 84 | Integration of Optimized Carbon Aerogels in Supercapacitors - P. Hartmut, C. Schmitt, and J. Fricke (University of Wurzburg) | |
| 10:15 | Fifteen-Minute Intermission | ||
| 10:30 | 85 | Recent Developments in Carbon-based Electrochemical Capacitor - A. Burke (University of California-Davis) | |
| 11:00 | 86 | SrRuO3 Perovskite based Compounds for Supercapacitors: Synthesis, Structure and Electrochemical Performance - M. Wohlfahrt-Mehrens, J. Schenk, H. Dittrich, P. Axmann, and J. Garche (Center for Solar Energy and Hydrogen Research, ZSW) | |
| 11:15 | 87 | Molybdenum Oxide/Carbon Composite Electrodes as Electrochemical Supercapacitors - W. Sugimoto, T. Ohnuma, Y. Murakami, and Y. Takasu (Shinshu University) | |
| 11:30 | 88 | Development of Low Cost Composites for Supercapacitors - H. Kim and B.N. Popov (University of South Carolina) | |
| 11:45 | 89 | Examination of Linear Potential Sweep Methods for Determining the Capacitance of Hydrous Ruthenium Oxide Materials - M. Miles, T. Groshens, and C. Johnson (Naval Air Warfare Center Weapons Division) | |
| 12:00 | 90 | Determination of Double Layer Properties of Carbon Aerogels Electrodes using Probe Beam Deflection and AC Impedance - G.A. Planes, M.C. Miras, and C. Barbero (Universidad Nacional de Rio Cuarto) |
Co-Chairs: A. Gozdz and J. Thomas
| Time | Abs# | Title | View |
|---|---|---|---|
| 2:00 | 91 | Using Block Copolymers in Nanostructured Architectures in Lithium Batteries - D. Sadoway and A. Mayes (Massachusetts Institute of Technology) | |
| 2:30 | 92 | Characterisation of a Novel Polymer Electrolyte Based on a Plastizing Lithium Salt - J. MacCallum (University of St Andrews), M. Silva, S. Barros, M. Smith, and E. Fernandes (Universidade do Minho) | |
| 2:45 | 93 | Towards Room Temperature Performance for Lithium-Polymer Batteries. - J. Kerr (Lawrence Berkeley National Laboratory,), W. Halley (University of Minnesota), and L. Curtiss (Argonne National Laboratory) | |
| 3:00 | 94 | PEO-LiBETI Dry Polymer Electrolyte for EV Lithium Batteries - S. Passerini, G. Appetecchi, P. Villano, M. Carewska (ENEA, C.R. Casaccia), and M. Puppo (FERRANIA S.p.A) | |
| 3:15 | 95 | Condition That a Pure PC Electrolyte Is Stable during the Iinsertion of Li at the Well Graphitized Anode - T. Takamura (Petoca, Ltd.), K. Yamaguchi, S. Aoki, A. Shimokawa, and K. Sekine (Rikkyo University) | |
| 3:30 | 96 | Ionic Conductivity of New Thermally Stable Polymer Electrolyte for Lithium-Ion Batteries - M. Saito (Tokyo Institute of Technology), T. Yabe (NOF Corporation), H. Ikuta, Y. Uchimoto, and M. Wakihara (Tokyo Institute of Technology) | |
| 3:45 | 97 | Temperature Dependence of the Conductivity of Lithium-Ion Battery Eectrolytes - B. Ravdel (Lithion, Inc.), K.M. Abraham (e-KEM Consulting), R. Gitzendanner, and C. Marsh (Lithion, Inc.) | |
| 4:00 | Thirty-Minute Intermission | ||
| 4:30 | 98 | The Effect of Lithium Salts on the Stability of Plastic Li-ion Batteries with Bonded Microporous Separators at Room and Elevated Temperatures - A.S. Gozdz and I. Plitz (Telecordia Technologies) | |
| 4:45 | 99 | Effect of Water and Oxygen on the Thermal Stability of LiPF_6 EC:EMC Electrolyte for Lithium Ion Batteries - G. Botte, Y. Wulandari (University of Minnesota Duluth), R. White (University of South Carolina), and Z. Zhang (Celgard, Inc) | |
| 5:00 | 100 | A Novel DSC Method to Study Electrode/Electrolyte Reactions - D. MacNeil and J. Dahn (Dalhousie University) | |
| 5:15 | 101 | Solvent Reduction and SEI Layer Formation: Theory and Experiments - P. Balbuena, Y. Wang (University of South Carolina), S. Nakamura, and M. Ue (Mitsubishi Chemical Corporation) | |
| 5:30 | 102 | Studies on Solvation of Lithium Ions in Mixed Organic Electrolyte Solutions by Electrospray Ionization Mass Spectroscopy - Y. Matsuda, T. Fukushima, H. Hashimoto, and R. Arakawa (Kansai University) |
Co-Chairs: A. Mayes and Z. Ogumi
| Time | Abs# | Title | View |
|---|---|---|---|
| 8:00 | 103 | Prediction of Reduction and Oxidation Potentials with Quantum Chemical Methods, and an Evaluation of Reduction Mechanisms for Alkyl Carbonates - J. Vollmer, L. Curtiss, C.-H. Chen, D. Vissers, and K. Amine (Argonne National Laboratory) | |
| 8:15 | 104 | Solvent Decomposition in Li-Ion Battery Electrolyte by DFT Calculations - K. Tasaki (MC Research and Innovation) | |
| 8:30 | 105 | Reactivity of Li-ion Battery Electrolytes - J. Kerr, S. Sloop, and K. Kinoshita (Lawrence Berkeley National Laboratory) | |
| 8:45 | 106 | A Comparison of the Reactivity of Cathode/Electrolyte Pairs Depending on the Salt Type - D. MacNeil and J. Dahn (Dalhousie University) | |
| 9:00 | 107 | Ionic Conductivity and Electrochemical Properties of Lithium Orthoborate Salts - W. Xu and C.A. Angell (Arizona State University) | |
| 9:15 | 108 | Superior Performance of Fluorocarbonate Electrolytes over the conventional Electrolytes in Li-ion Half-cells - G. Nagasubramanian (Sandia National Laboratories) | |
| 9:30 | 109 | Synthesis of New Li-Fluoroalkyl-Phosphates (LiFAP) for the Application in Li-Ion Batteries - N. Ignatiev, M. Schmidt, A. Kuehner, U. Heider, V. Hilarius, and R. Oesten (Merck KGaA) | |
| 9:45 | 110 | Gel-type, Poly(ethylene oxide)-based Electrolytes for Lithium Batteries. - G.B. Appetecchi, Y. Aihara, and B. Scrosati (University "La Sapienza") | |
| 10:00 | Thirty-Minute Intermission | ||
| 10:30 | 111 | Investigations of Electrolyte Additives in Lithium-ion Batteries - X. Zhang, R. Kostecki, T. Richardson (Lawrence Berkeley National Lab), J. Pugh (Valence Technology), and P. Ross (Lawrence Berkeley National Lab) | |
| 10:45 | 112 | A New Additive for Lithium Battery Electrolytes Based on an Alkyl Borate Compound and Its Effect on Improvement of the Elevated Temperature Cycling of Spinel LiMn2O4 Cathode - X. Sun, H.S. Lee, X.-Q. Yang, and J. McBreen (Brookhaven National Laboratory) | |
| 11:00 | 113 | Electrochemical Properties of the Solid Lithium-Conducting Electrolyte/Electrode Material Interface - E. Shembel, P. Novak, T. Pastushkin, V. Redko, Y. Kalinushkin (Ener1), A. Markevich, A. Kvasha, K. Kylyvnyk, V. Khandetsky, A. Nosenko, and S. Oleshko (Ukrainian State Chemical Technology University) | |
| 11:15 | 114 | Initiator Effect on the Performance of the Lithium Ion Polymer Batteries based on the Polymer Electrolytes prepared by Free Radical Polymerization - K.H. Lee, K.H. Kim, and H.S. Lim (Samsung SDI Co., LTD) | |
| 11:30 | 115 | Novel Microporous Gelling Separator Membrane for Lithium Ion Polymer Battery - S.-J. Lee, J.Y. Cho, S.-Y. Lee, S. Park, B.I. Park, H.H. Yong, H.-K. Lee, H.-M. Lee, H.-S. Song, and S. Ahn (LG Chemical Ltd.) | |
| 11:45 | 116 | The Transport Properties of Lithium Electrolyte Solution Coexisting with the Porous Solid Materials - M. Mizuhata, G. Cha, I. Shige, A. Kajinami, and S. Deki (Kobe University) |
Co-Chairs: P.N. Ross and P. Zhang
| Time | Abs# | Title | View |
|---|---|---|---|
| 2:00 | 117 | Liquid Range of Binary Solvents of Common Carbonates for Lithium Batteries - M. Ding, K. Xu, S. Zhang, J. Allen, R. Jow, and K. Amine (Army Research Laboratory) | |
| 2:30 | 118 | Effect of Phosphorous-based Fire-retardants in Electrolytes on Performance of Li-ion Cells - K. Xu, M. Ding, S. Zhang, J. Allen, and R. Jow (U. S. Army Research Laboratory) | |
| 2:45 | 119 | Application of Functionalized SiO2 in PEO based Polymer Electrolyte - J. Lee and Y. Liu (National University of Singapore) | |
| 3:00 | 120 | The Electrochemical Properties of Composite Polymeric Electrolytes Reinforced with Glass-Fibre Cloth for Li-ion Battery - J.M. Ko, D.-W. Kim, and J.-H. Chun (Hanbat National University) | |
| 3:15 | 121 | Improved Low Temperature Performance of Lithium Ion Cells with Low Ethylene Carbonate (EC) Content Electrolytes - M. Smart, R. Bugga, S. Surampudi (California Institute of Technology), H. Croft, D. Tice, and R. Staniewicz (SAFT America, Inc.) | |
| 3:30 | 122 | A Sealed Optical Cell for the Study of the Lithium Electrode/Electrolyte Interface - P.C. Howlett, D.R. MacFarlane (Monash University), and A.F. Hollenkamp (CSIRO) | |
| 3:45 | 123 | In Situ AFM Observation of Lithium Deposition in the Presence of Film-Forming Additives - M. Inaba, R. Mogi, T. Abe, and Z. Ogumi (Kyoto University) | |
| 4:00 | Thirty-Minute Intermission | ||
| 4:30 | 124 | Rotating Ring Disk Electrode Studies of Solvent Reduction and Oxidation - X. Zhang, T. Richardson, and P. Ross (Lawrence Berkeley National Lab) | |
| 4:45 | 125 | Electrochemistry of Molten Nitrate Electrolytes and Applications for High Voltage Lithium Cells - M.H. Miles (Naval Air Warfare Center Weapons Division) | |
| 5:00 | 126 | Ionic Liquid Electrolytes - A. McEwen (Covalent Associates, Inc.) | |
| 5:15 | 127 | Polymer Electrolytes Based on Ionic Liquids - A. Lewandowski and A. Swiderska (Poznan University of Technology) |
Co-Chairs: F.R. McLarnon and F. Maleki
| Time | Abs# | Title | View |
|---|---|---|---|
| 8:30 | 128 | Aging Mechanism in Lithium Ion Cells - B. Michel, B. Philippe, and H. Sylvie (SAFT) | |
| 9:00 | 129 | Calendar Life Modeling Methodology for High-Power PNGV Saft Batteries - J. Belt, C. Motloch, R. Wright (Idaho National Engineering and Environmental Laboratory), K. Nechev, and G. Chagnon (SaftAmerica Inc.) | |
| 9:15 | 130 | Cycle Life Modeling of Advanced Technology Development Program Gen 1 Lithium Ion Cells - R. Wright and C. Motloch (Idaho National Engineering and Environmental Laboratory) | |
| 9:30 | 131 | Aging and Life Analyses of Generation 2 Advanced Technology Development Lithium-Ion Cells - C. Motloch, J. Christophersen, R. Wright (Idaho National Engineering and Environmental Laboratory), and V. Battaglia (Argonne National Laboratory) | |
| 9:45 | 132 | Accelerated Life Testing and Data Analysis for Lithium-Ion Cells - R. Jungst, G. Nagasubramanian, T. Unkelhaeuser, A. Urbina, T. Paez, and D. Doughty (Sandia National Laboratories) | |
| 10:00 | Thirty-Minute Intermission | ||
| 10:30 | 133 | Simulation of a High-Power Lithium-ion Battery - T. Abe, Y. Ohsawa, H. Horie, T. Ogawa, Y. Tanjo, and M. Kawai (Nissan Motor Co.,Ltd.) | |
| 11:00 | 134 | Calendar Life Modeling of Advanced Technology Development Program Gen 1 Lithium Ion Cells - R. Wright and C. Motloch (Idaho National Engineering and Environmental Laboratory) | |
| 11:15 | 135 | Ac Impedance Analysis on Commercial Li Ion Battery - T. Momma, K. Tsuchiya, and T. Osaka (Waseda University) | |
| 11:30 | 136 | Impedance Simulation of A Lithium-ion Battery: Validity of Solid Phase Diffusion Coefficient Estimation - Q. Guo, V. Subramanian, J. Weidner, and R. White (University of South Carolina) | |
| 11:45 | 137 | Two- and Three-electrode Impedance Spectroscopy Studies for Lithium-ion Batteries - J.-Y. Song, H.-H. Lee, Y.-Y. Wang, and C.-C. Wan (National Tsing-Hua University) |
Co-Chairs: G. Chagnon and D.H. Doughty
| Time | Abs# | Title | View |
|---|---|---|---|
| 2:00 | 138 | Using the Active Component Concentration Profile to Control High Power Charging of HEV Battery Pack - V. Pavlovic and R. Field (Edison Minit-Charger® Technology Center) | |
| 2:15 | 139 | Design, Performance and Safety of PolyStor's Lithium-Ion Polymer Gel Batteries - F. Coustier, G. Nagarajan, and D. Fouchard (PolyStor Corporation) | |
| 2:30 | 140 | Superconformal Electrodeposition of Copper - T. Moffat, D. Wheeler, W. Huber, and D. Josell (National Institute of Standards and Technology) | |
| 2:45 | 141 | Importance of Thermal Management of Lithium Ion Cell - Y. Mita, H. Miyashiro, Y. Kobayashi, and T. Iwahori (Central Research Institute of Electric Power Industry) | |
| 3:00 | 142 | Thermal Modeling of LI-ION Cells - V. Srinivasan (Pennsylvania State University), W.B. Gu (GM Alternative Propulsion Center), and C.-Y. Wang (Pennsylvania State University) | |
| 3:15 | 143 | Thermal Stability Studies of Li-ion Cells and Components under Overcharged Conditions - H. Maleki and J. Howard (Motorola, Inc.) | |
| 3:30 | 144 | Tailoring the Ragone Plot Through Microstructural Design of Battery Electrodes - Y.-M. Chiang and B. Hellweg (Massachusetts Institute of Technology) | |
| 3:45 | 145 | Combi-Electrochemistry: Exploring the Phase Diagram of New Materials for Advanced Batteries - K. Hewitt, A. Bonakdarpour, D. MacNeil, Z. Chen, and J. Dahn (Dalhousie University) | |
| 4:00 | Thirty-Minute Intermission | ||
| 4:30 | 146 | Capacity Fade of Li-ion Cells at Elevated Temperatures Cycled Using Pulse and DC Charging Protocols - B. Popov, P. Ramadass, B. Haran, A. Durairajan, H. Soto, and R. White (University of South carolina) | |
| 4:45 | 147 | Power Fade in High-Rate Lithium-Ion Batteries - J. McBreen, M. Balasubramanian, X. Sun, and X.-Q. Yang (Brookhaven National Laboratory) | |
| 5:00 | 148 | Analysis of Pulse Discharge of a Lithium-Ion Battery - P. Gomadam, J. Weidner, and R. White (University of South Carolina) | |
| 5:15 | 149 | Polymerization Additives for Overcharge Protection in Lithium Ion Batteries - T. Richardson and P. Ross (Lawrence Berkeley National Laboratory) | |
| 5:30 | 150 | Thin Film Formation of LiCoO2, LiMn2O4, and Li4T12For Rechargeable Lithium Batteries - K. Kanamura, Y.H. Rho, M. Fujisaki, and T. Umegaki (Tokyo Metropolitan University) |
Co-Chairs: B. Scrosati and E.S. Takeuchi
| Time | Abs# | Title | View |
|---|---|---|---|
| 8:30 | 151 | Effect of Binders on the Surface Morphology and Adhesion Strength in the Anodes of Lithium Ion Batteries - M. Yoo, C. Frank (Stanford University), S. Mori, and K. Tasaki (Mitsubishi Chemical Corporation) | |
| 8:45 | 152 | Performance and Safety Testing of Lithium-ion Cells Containing Flame-Retardant Additives - R. Gitzendanner, B. Ravdel, C. Marsh (Yardney Technical Products, Inc.), and B. Lucht (University of Rhode Island) | |
| 9:00 | 153 | Lithium/Sulfur Rechargeable Cells: Effect of Carbon and Binder on Sulfur Electrode Performance - J. Shim, K. Striebel, and E. Cairns (Lawrence Berkeley National Laboratory) | |
| 9:15 | 154 | Discharge Process of Li/polymer Electrolyte/S Cell at Room Temperature - H.-J. Ahn (Gyeongsang National University), J.-Y. Lee (Korea Advanced Institute of Sience & Technology), K.-W. Kim, B.-Y. Hur, J.-H. Ahn, H.-S. Ryu, and K.-Y. Kang (Gyeongsang National University) | |
| 9:30 | 155 | Characterization of Electrodeposited Carbon in Molten Carbonates and Application to Lithium Batteries - B. Kaplan, H. Groult (Universite Pierre & Marie Curie), S. Komaba (Iwate University), V. Gupta, T. Nakajima (Aichi Institute of Technology), and N. Kumagai (Iwate University) | |
| 9:45 | 156 | Optimal Sizing of a Li-Ion Battery, a Fuel Cell and a Capacitor for a Hybrid Power System - R. Gundala, J. Weidner, and R. White (University of South Carolina) | |
| 10:00 | Thirty-Minute Intermission | ||
| 10:30 | 157 | Changes of the Lithium Battery Voltage Conditioned by Alterations of the Lithium's Electrodes Passive Film During a Battery Discharge and Recovery - A. Shekhtman (KVANT) | |
| 10:45 | 158 | Pecularities of Functioning of Studeied Systems, as Link Between Their Physical and Chemical Properties and Their Consumption Properties, Researched by Means of the Research Method and Methofd of the Characteristic Transformation - A. Shekhtman (KVANT) | |
| 11:00 | 159 | Lithium Fuel Cells. 50:50 MEEP-PhO Swelling Effect of Polyphosphazene Membranes for Primary Aqueous Lithium Battery Systems - M. Urquidi-Macdonald, H. Allcock, H. Castaneda, and A. Cannon (The Pennsylvania State University) | |
| 11:15 | 160 | A Sodium Battery Using Room Temperature Ionic Liquids - S. Park, J. Winnick, and P. Kohl (Georgia Institute of Technology) |