Abstract
Operando studies of solid-state batteries (SSBs) must capture device-relevant stack pressure and temperature, since uncontrolled conditions can cause relaxation artifacts and lead to false mechanistic interpretations. To address this, we developed an operando framework for X-ray diffraction (XRD) and X-ray spectroscopy (XAS) with precisely controlled dynamic pressure and temperature, deployable across three platforms: (i) scanning microbeam transmission XRD for spatiotemporal mapping of reaction fronts, state-of-charge gradients, and stress localizations; (ii) coupled transmission XRD-XAS for simultaneous tracking of structural and redox evolution; and (iii) laboratory XRD for real-time monitoring of phase transformations during operation. Validated on sulfide-electrolyte SSBs with Li-In anodes and LiNi(0.8)Mn(0.1)Co(0.1)O(2) (NMC811) or LiCoO(2) (LCO) cathodes, the framework yields consistent high-quality datasets, which reveal cross-sectional lattice-parameter evolution, spatiotemporal changes in stress gradients, and alteration of structural and redox pathways. By enabling pressure-aware operando XRD and XAS characterization, this framework provides a transferable platform and methodology to minimize artifactual interpretations, ensure reproducible benchmarking, and accelerate mechanistic discovery in next-generation solid-state batteries.