“…[3][4][5] A key concern in these and other solid electrolytes, however, is their mechanical stability in the presence of strains in the adjacent electrode materials accompanying reversible Li storage (intercalation or alloying) that may vary from a few percent by volume up to a factor of three (e.g., in the case of silicon anodes). [6,7] Sulfide-based electrolytes have remarkably lower Young's modulus (~20 GPa [8] ) than many of these active materials (e.g., 100-200 GPa), as well as oxide-based solid electrolytes such as the garnets (100-200 GPa for Li 7 La 3 Zr 2 O 12 or LLZO and Li 0.33 La 0.57 TiO 3 or LLTO [8][9][10] ), which initially suggested to us that the sulfides might exhibit superior strainaccommodation characteristics in solid state batteries. However, detailed understanding of elastoplastic and fracture properties, which has heretofore been lacking, is required to draw clear conclusions of material design and selection for sulfide solid electrolytes.…”