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Abstract Li‐stuffed battery materials intrinsically have surface impurities, typically Li 2 CO 3 , which introduce severe kinetic barriers and electrochemical decay for a cycling battery. For energy‐dense solid‐state lithium batteries (SSLBs), mitigating detrimental Li 2 CO 3 from both cathode and electrolyte materials is required, while the direct removal approaches hardly avoid Li 2 CO 3 regeneration. Here, a decarbonization–fluorination strategy to construct ultrastable LiF‐rich interphases throughout the SSLBs by in situ reacting Li 2 CO 3 with LiPF 6 at 60 °C is reported. The fluorination of all interfaces effectively suppresses parasitic reactions while substantially reducing the interface resistance, producing a dendrite‐free Li anode with an impressive cycling stability of up to 7000 h. Particularly, transition metal dissolution associated with gas evolution in the cathodes is remarkably reduced, leading to notable improvements in battery rate capability and cyclability at a high voltage of 4.5 V. This all‐in‐one approach propels the development of SSLBs by overcoming the limitations associated with surface impurities and interfacial challenges.
Guo et al. (Fri,) studied this question.
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