An analysis of rechargeable lithium-ion batteries after prolonged cycling
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Doron Aurbach | Hyeong-Jin Kim | Boris Markovsky | D. Aurbach | B. Markovsky | E. Levi | Hyeong-Jin Kim | M. Cojocaru | A. Rodkin | Elena Levi | A Rodkin | Miriam Cojocaru
[1] John B. Goodenough,et al. AC impedance analysis of polycrystalline insertion electrodes: application to Li1−xCoO2 , 1985 .
[2] D. Aurbach,et al. Ethylmethylcarbonate, a Promising Solvent for Li‐Ion Rechargeable Batteries , 1996 .
[3] Minoru Inaba,et al. Impedance Study on the Electrochemical Lithium Intercalation into Natural Graphite Powder , 1998 .
[4] D. Aurbach,et al. New insights into the interactions between electrode materials and electrolyte solutions for advanced nonaqueous batteries , 1999 .
[5] Ralph E. White,et al. Characterization of Commercially Available Lithium-Ion Batteries , 1998 .
[6] H. Tamura,et al. Morphology and chemical compositions of surface films of lithium deposited on a Ni substrate in nonaqueous electrolytes , 1995 .
[7] D. Scherson,et al. Electrochemical characterization of lithiated transition metal oxide cathode particles in the absence of carbon, binders and other additives , 1999 .
[8] Anton Van der Ven,et al. Phase diagrams of lithium transition metal oxides: investigations from first principles , 1999 .
[9] D. Aurbach,et al. Common Electroanalytical Behavior of Li Intercalation Processes into Graphite and Transition Metal Oxides , 1998 .
[10] Doron Aurbach,et al. Failure and Stabilization Mechanisms of Graphite Electrodes , 1997 .
[11] Doron Aurbach,et al. Solid‐State Electrochemical Kinetics of Li‐Ion Intercalation into Li1 − x CoO2: Simultaneous Application of Electroanalytical Techniques SSCV, PITT, and EIS , 1999 .
[12] J. Besenhard,et al. Handbook of Battery Materials , 1998 .
[13] Madhav Datta,et al. Energy storage systems for electronics , 2000 .
[14] Rachid Yazami,et al. Surface chemistry and lithium storage capability of the graphite-lithium electrode , 1999 .
[15] K. Abraham,et al. Discharge Rate Capability of the LiCoO2 Electrode , 1998 .
[16] D. Aurbach. Review of selected electrode–solution interactions which determine the performance of Li and Li ion batteries , 2000 .
[17] D. Aurbach,et al. Electrochemical and spectroscopic studies of carbon electrodes in lithium battery electrolyte systems , 1993 .
[18] P. Kumta,et al. Synthesis of LiCoO2 powders for lithium-ion batteries from precursors derived by rotary evaporation , 1998 .
[19] Doron Aurbach,et al. A Comparative Study of Synthetic Graphite and Li Electrodes in Electrolyte Solutions Based on Ethylene Carbonate‐Dimethyl Carbonate Mixtures , 1996 .
[20] 山本 治,et al. Lithium ion batteries : fundamentals and performance , 1998 .
[21] Y. Chiang,et al. Synthesis of LiCoO2 by Decomposition and Intercalation of Hydroxides , 1998 .
[22] Petr Novák,et al. Insertion Electrode Materials for Rechargeable Lithium Batteries , 1998 .
[23] Young-Min Choi,et al. Lithium transport through porous Li1−δCoO2 electrode: analysis of current transient , 1998 .
[24] G. Pistoia,et al. Lithium batteries : new materials, developments, and perspectives , 1994 .
[25] Doron Aurbach,et al. Diffusion Coefficients of Lithium Ions during Intercalation into Graphite Derived from the Simultaneous Measurements and Modeling of Electrochemical Impedance and Potentiostatic Intermittent Titration Characteristics of Thin Graphite Electrodes , 1997 .
[26] Stephane Levasseur,et al. The insulator-metal transition upon lithium deintercalation from LiCoO2: electronic properties and 7Li NMR study , 1999 .
[27] Doron Aurbach,et al. On the correlation between surface chemistry and performance of graphite negative electrodes for Li ion batteries , 1999 .