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Why charging Li-air batteries with current low-voltage mediators is slow and singlet oxygen does not explain degradation.

Sunyhik AhnCeren ZorSixie YangMarco LagnoniDaniel DewarTammy NimmoChloe ChauMax JenkinsAlexander J KiblerAlexander PatemanGregory J ReesXiangwen GaoPaul AdamsonNicole GrobertAntonio BerteiLee R JohnsonPeter G Bruce
Published in: Nature chemistry (2023)
Although Li-air rechargeable batteries offer higher energy densities than lithium-ion batteries, the insulating Li 2 O 2 formed during discharge hinders rapid, efficient re-charging. Redox mediators are used to facilitate Li 2 O 2 oxidation; however, fast kinetics at a low charging voltage are necessary for practical applications and are yet to be achieved. We investigate the mechanism of Li 2 O 2 oxidation by redox mediators. The rate-limiting step is the outer-sphere one-electron oxidation of Li 2 O 2 to LiO 2 , which follows Marcus theory. The second step is dominated by LiO 2 disproportionation, forming mostly triplet-state O 2 . The yield of singlet-state O 2 depends on the redox potential of the mediator in a way that does not correlate with electrolyte degradation, in contrast to earlier views. Our mechanistic understanding explains why current low-voltage mediators (<+3.3 V) fail to deliver high rates (the maximum rate is at +3.74 V) and suggests important mediator design strategies to deliver sufficiently high rates for fast charging at potentials closer to the thermodynamic potential of Li 2 O 2 oxidation (+2.96 V).
Keyphrases
  • ion batteries
  • solid state
  • electron transfer
  • hydrogen peroxide
  • magnetic resonance imaging
  • computed tomography