质谱法
热的
材料科学
分析化学(期刊)
化学
热分析
热电离质谱法
大规模运输
热力学
化学物理
作者
Yuying Zhang,Chao Wang,Jihao Zhang,Hanwei Liu,Jianwen Wang,Zhenzhong Li,Wencheng Su,Wei Zhou,Wenbo Zhai,Jiahe Zang,Shaofei Wang,Qingyu Kong,Chunzhen Yang
标识
DOI:10.1021/acsenergylett.6c00367
摘要
Understanding the intrinsic thermal instability of Ni-rich cathodes is critical for elucidating the thermal runaway mechanisms in lithium-ion batteries. Here, we investigate the thermally induced decomposition of Ni-rich cathodes under electrolyte-free conditions using time-resolved operando approaches, including X-ray diffraction (XRD), X-ray absorption spectroscopy (XAS), and online mass spectrometry (OMS). The results reveal a coupled evolution of oxygen release, Ni redox, and structural transformations during heating. Oxygen release is initiated prior to detectable bulk phase transition and correlates with early structural disorder, as tracked by the evolution of the (003)L and (104)L reflections. Deep delithiation at 4.8 V (∼95% SOC) accelerates Ni reduction and amplifies structural instability, leading to approximately 3-fold higher early stage oxygen release compared with the 4.3 V (∼85% SOC) condition. These findings establish a coupling-based framework for understanding cathode-driven thermal instability and provide guidance for improving battery safety.
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