Abstract
The ever‐growing demand for high‐energy lithium‐ion batteries in portable electronics and electric vehicles has triggered intensive research efforts over the past decade. An efficient strategy to boost the energy and power density of lithium‐ion batteries is to increase the Ni content in the cathode materials. However, a higher Ni content in the cathode materials gives rise to safety issues. Herein, thermal expansion and oxygen vacancies are proposed as new critical factors that affect the thermal stability of charged Ni‐rich cathode materials based on a systematic synchrotron‐based X‐ray study of Li0.33Ni0.5+ xCo0.2Mn0.3‐ xO2 (x = 0, 0.1, 0.2) cathode materials during a heating process. Charged cathode materials with higher Ni contents show larger thermal expansion, which accelerates transition metal migration to the Li layers. Oxygen vacancies are formed and accumulate mainly around Ni ions until the layered‐to‐spinel phase transition begins. The oxygen vacancies also facilitate transition metal migration to the Li layers. Thermal expansion and the presence of oxygen vacancies decrease the energy barrier for cation migration and facilitate the phase transitions in charged cathode materials during the heating process. These results provide valuable guidance for developing new cathode materials with improved safety characteristics.
Highlights
Lithium-ion batteries, the most successful electrochemical energy conversion and storage system far, have been utilized in electric vehicles and energy storage sys-a higher Ni content in the cathode materials gives rise to safety tems as a part of smart grids and portable issues
The X-ray diffraction (XRD) patterns of these cathode materials can be indexed to a hexagonal layered phase with the R3̄m space group
The thermal decomposition process of charged Li0.33Ni0.5+xCo0.2Mn0.3-xO2 (x = 0, 0.1, 0.2) cathode materials was systematically investigated using a combination of synchrotronbased XRD, X-ray absorption spectroscopy (XAS), and a thermoanalytical differential scanning calorimetry (DSC) technique
Summary
Lithium-ion batteries, the most successful electrochemical energy conversion and storage system far, have been utilized in electric vehicles and energy storage sys-. Thermal expansion and the presence of oxygen vacancies decrease the energy barrier for cation rious safety problems in harsh thermal environments due to their inherent thermal instability.[7,8,9,10] The thermal runaway and catastrophic failure of lithium-ion batteries are the result of the uncontrollable exothermigration and facilitate the phase transitions in charged cathode materials mic reactions, which mainly originate from during the heating process. These results provide valuable guidance for the reaction between released oxygen and developing new cathode materials with improved safety characteristics.
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