AI Article Synopsis
- Transition metal dissolution is known to degrade battery anodes, but its effects on cathodes, specifically LiMnO, are less understood.
- The study finds that capacity fading in LiMnO cathodes is linked to structural changes and the dissolution of manganese, creating a harmful cycle that reduces battery performance.
- Using lithium-rich LiMnO with specific structural characteristics can help minimize these issues, potentially leading to longer-lasting batteries.
Article Abstract
Historically long accepted to be the singular root cause of capacity fading, transition metal dissolution has been reported to severely degrade the anode. However, its impact on the cathode behavior remains poorly understood. Here we show the correlation between capacity fading and phase/surface stability of an LiMnO cathode. It is revealed that a combination of structural transformation and transition metal dissolution dominates the cathode capacity fading. LiMnO exhibits irreversible phase transitions driven by manganese(III) disproportionation and Jahn-Teller distortion, which in conjunction with particle cracks results in serious manganese dissolution. Meanwhile, fast manganese dissolution in turn triggers irreversible structural evolution, and as such, forms a detrimental cycle constantly consuming active cathode components. Furthermore, lithium-rich LiMnO with lithium/manganese disorder and surface reconstruction could effectively suppress the irreversible phase transition and manganese dissolution. These findings close the loop of understanding capacity fading mechanisms and allow for development of longer life batteries.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC6797712 | PMC |
| http://dx.doi.org/10.1038/s41467-019-12626-3 | DOI Listing |
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