Characterization of Polycrystalline Cathode Materials in Five Dimensions (5D)

Abstract

Thermal stability is one of the most desired features for large-scale energy applications, such as batteries used in electronics and electric vehicles. Thermal runaway, heat generation, and gas release are likely to happen for batteries under thermal abuse conditions, leading to severe performance degradation and safety risks. Although the decomposition of electrolytes at high temperatures has been widely studied in the community, a systematic and in situ study of the intrinsic instability of the cathodes in Li ion batteries is lacking. Polycrystalline nickel-rich Li layered oxides (LiNi x Mn y Co1-x-y O2, NMC) were chosen as the platform materials considering the recent improvements in specific capacity but also the rising safety concerns in Ni-rich cathodes.Here we used one of state-of-the-art techniques in microscopy: the full-field transmission X-ray microscope (TXM) to capture the 3D tomography of charged NMC particles, together with the X-ray absorption near edge structure (XANES) spectroscopic capability for Ni oxidation state. Moreover, we performed the XANES-3DTXM measurements during the whole process of heating the NMC cathodes from room temperature up to 250°C, which enables us to monitor the full evolution of NMC secondary particles in real time in 5 dimensions (3D spatial + tunable X-ray energy + temperature).This in situ XANES-3DTXM approach allows us to observe the real-time morphological and chemical evolution at elevated temperatures. The large field of view and reasonably high spatial resolution offer the capability to analyze NMC cathodes at different length scales, ranging from voids of tens of nanometers, to cracks of hundreds of nanometers, to secondary particles of tens of micrometers.With quantification of morphological (e.g., relative volume change, porosity, crack propagation) and chemical (e.g., the oxidation state of Ni, local charge distribution) characteristics as a function of temperature and time, the fundamental degradation mechanisms in polycrystalline nickel-rich Li layered oxides under thermally abuse conditions are thereupon unveiled. Based on these analyses and discoveries, we proposed to alter the primary particle arrangement as an effective solution to alleviate the thermal issues in nickel-rich Li layered oxides.Figure: Schematic of the in situ heating setup, 3D rendering of a NMC secondary particle, and selected morphology section and Ni oxidation state mapping at different temperatures. Figure 1