AI Article Synopsis
- - Conversion-type electrodes are gaining attention for their high-capacity potential in batteries, but their unstable cycles, especially in water-based systems, limit their effectiveness due to structural issues during repeated use.
- - Researchers propose using an amorphous bismuth sulfide (a-BS) that promotes optimal ion diffusion and bond stability, preventing the breakdown of key connections in the material.
- - Testing shows that the a-BS electrode significantly improves battery performance, achieving over 8000 charging cycles while maintaining a high capacity of 326.7 mAh/g and stable energy density, indicating a promising advancement for aqueous battery storage solutions.
Article Abstract
Conversion-type electrodes offer a promising multielectron transfer alternative to intercalation hosts with potentially high-capacity release in batteries. However, the poor cycle stability severely hinders their application, especially in aqueous multivalence-ion systems, which can fundamentally impute to anisotropic ion diffusion channel collapse in pristine crystals and irreversible bond fracture during repeated conversion. Here, an amorphous bismuth sulfide (a-BS) formed in situ with unprecedentedly self-controlled moderate conversion Cu storage is proposed to comprehensively regulate the isotropic ion diffusion channels and highly reversible bond evolution. Operando synchrotron X-ray diffraction and substantive verification tests reveal that the total destruction of the Bi─S bond and unsustainable deep alloying are fully restrained. The amorphous structure with robust ion diffusion channels, unique self-controlled moderate conversion, and high electrical conductivity discharge products synergistically boosts the capacity (326.7 mAh g at 1 A g ), rate performance (194.5 mAh g at 10 A g ), and long-lifespan stability (over 8000 cycles with a decay rate of only 0.02 ‰ per cycle). Moreover, the a-BS Cu ‖Zn hybrid ion battery can well supply a stable energy density of 238.6 Wh kg at 9760 W kg . The intrinsically high-stability conversion mechanism explored on amorphous electrodes provides a new opportunity for advanced aqueous storage.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10787086 | PMC |
| http://dx.doi.org/10.1002/advs.202304146 | DOI Listing |
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