Detecting dynamic structural evolution based on in-situ high-energy X-ray diffraction technology for sodium layered oxide cathodes

The detrimental phase transformations of sodium layered transition metal oxides (Na_xTMO₂) during desodiation/sodiation seriously suppress their practical applications for sodium ion batteries (SIBs). Undoubtedly, comprehensively investigating of the dynamic crystal structure evolutions of Na_xTMO₂ associating with Na ions extraction/intercalation and then deeply understanding of the relationships between electrochemical performances and phase structures drawing support from advanced characterization techniques are indispensable. In-situ high-energy X-ray diffraction (HEXRD), a powerful technology to distinguish the crystal structure of electrode materials, has been widely used to identify the phase evolutions of Na_xTMO₂ and then profoundly revealed the electrochemical reaction processes. In this review, we begin with the descriptions of synchrotron characterization techniques and then present the advantages of synchrotron X-ray diffraction (XRD) over conventional XRD in detail. The optimizations of structural stability and electrochemical properties for P2-, O3-, and P2/O3-type Na_xTMO₂ cathodes through single/dual-site substitution, high-entropy design, phase composition regulation, and surface engineering are summarized. The dynamic crystal structure evolutions of Na_xTMO₂ polytypes during Na ion extraction/intercalation as well as corresponding structural enhancement mechanisms characterizing by means of HEXRD are concluded. The interior relationships between structure/component of Na_xTMO₂ polytypes and their electrochemical properties are discussed. Finally, we look forward the research directions and issues in the route to improve the electrochemical properties of Na_xTMO₂ cathodes for SIBs in the future and the combined utilizations of multiple characterization techniques. This review will provide significant guidelines for rational designs of high-performance Na_xTMO₂ cathodes.