Abstract
Non‐aqueous Li–O2 batteries are promising for next‐generation energy storage. New battery chemistries based on LiOH, rather than Li2O2, have been recently reported in systems with added water, one using a soluble additive LiI and the other using solid Ru catalysts. Here, the focus is on the mechanism of Ru‐catalyzed LiOH chemistry. Using nuclear magnetic resonance, operando electrochemical pressure measurements, and mass spectrometry, it is shown that on discharging LiOH forms via a 4 e− oxygen reduction reaction, the H in LiOH coming solely from added H2O and the O from both O2 and H2O. On charging, quantitative LiOH oxidation occurs at 3.1 V, with O being trapped in a form of dimethyl sulfone in the electrolyte. Compared to Li2O2, LiOH formation over Ru incurs few side reactions, a critical advantage for developing a long‐lived battery. An optimized metal‐catalyst–electrolyte couple needs to be sought that aids LiOH oxidation and is stable towards attack by hydroxyl radicals.
Highlights
Non-aqueous Li-O2 batteries are promising for generation energy storage
Published by some of the authors,[7] concerns the use of a soluble catalyst LiI, which catalyzes the LiOH formation with its H source solely coming from added H2O in the electrolyte; a subsequent study[9] confirmed the proposed 4 e- oxygen reduction reaction (ORR) on discharging
In the dimethyl sulfoxide (DMSO) case, it was suggested that at low water contents (~150 ppm), a mixture of Li2O2 and LiOH was formed on discharge, and that on charging, Li2O2 is first converted to LiOH, the latter getting decomposed by Ru catalysts at voltages of as low as ~3.2 V
Summary
Non-aqueous Li-O2 batteries are promising for generation energy storage. New battery chemistries based on LiOH, rather than Li2O2, have recently been reported in systems with added water, one using a soluble additive LiI and the other using solid Ru catalysts. [7] The other case employs a Ru-based solid catalyst in a water-added dimethyl sulfoxide (DMSO) or tetraglyme electrolyte.[8] Ru was proposed to catalyze LiOH formation and decomposition in a tetraglyme electrolyte with 4600 ppm water.
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