Abstract
The sulfide-based solid-state electrolytes (SEs) reactivity toward moisture and Li-metal are huge barriers that impede their large-scale manufacturing and applications in all-solid-state lithium batteries (ASSLBs). Herein, we proposed an Al and O dual-doped strategy for Li3PS4 SE to regulate the chemical/electrochemical stability of anionic PS43− tetrahedra to mitigate structural hydrolysis and parasitic reactions at the SE/Li interface. The optimized Li3.08Al0.04P0.96S3.92O0.08 SE presents the highest σLi+ of 3.27 mS cm−1, which is ∼6.8 times higher than the pristine Li3PS4 and excellently inhibits the structural hydrolysis for ∼25 min @ 25% humidity at RT. DFT calculations confirmed that the enhanced chemical stability was revealed to the intrinsically stable entities, e.g., POS33− units. Moreover, Li3.08Al0.04P0.96S3.92O0.08 SE cycled stably in Li//Li symmetric cell over 1000 h @ 0.1 mA cm−2/0.1 mA h cm−2, could be revealed to Li-Al alloy and Li2O at SE/Li interface impeding the growth of Li-dendrites during cycling. Resultantly, LNO@LCO/Li3.08Al0.04P0.96S3.92O0.08/Li-In cell delivered initial discharge capacities of 129.8 mA h g−1 and 83.74% capacity retention over 300 cycles @ 0.2 C at RT. Moreover, the Li3.08Al0.04P0.96S3.92O0.08 SE presented >90% capacity retention over 200 and 300 cycles when the cell was tested with LiNi0.8Co0.15Al0.05O2 (NCA) cathode material vs. 5 and 10 mg cm−2 @ RT.
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