Yuhui Chen scite author profile

When lithium-oxygen batteries discharge, O2 is reduced at the cathode to form solid Li2O2. Understanding the fundamental mechanism of O2 reduction in aprotic solvents is therefore essential to realizing their technological potential. Two different models have been proposed for Li2O2 formation, involving either solution or electrode surface routes. Here, we describe a single unified mechanism, which, unlike previous models, can explain O2 reduction across the whole range of solvents and for which the two previous models are limiting cases. We observe that the solvent influences O2 reduction through its effect on the solubility of LiO2, or, more precisely, the free energy of the reaction LiO2(*) ⇌ Li(sol)(+) + O2(-)(sol) + ion pairs + higher aggregates (clusters). The unified mechanism shows that low-donor-number solvents are likely to lead to premature cell death, and that the future direction of research for lithium-oxygen batteries should focus on the search for new, stable, high-donor-number electrolytes, because they can support higher capacities and can better sustain discharge.

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A Reversible and Higher-Rate Li-O ₂ Battery

Peng

Freunberger

Chen

et al. 2012

Science

1,826

1,469

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The rechargeable nonaqueous lithium-air (Li-O(2)) battery is receiving a great deal of interest because, theoretically, its specific energy far exceeds the best that can be achieved with lithium-ion cells. Operation of the rechargeable Li-O(2) battery depends critically on repeated and highly reversible formation/decomposition of lithium peroxide (Li(2)O(2)) at the cathode upon cycling. Here, we show that this process is possible with the use of a dimethyl sulfoxide electrolyte and a porous gold electrode (95% capacity retention from cycles 1 to 100), whereas previously only partial Li(2)O(2) formation/decomposition and limited cycling could occur. Furthermore, we present data indicating that the kinetics of Li(2)O(2) oxidation on charge is approximately 10 times faster than on carbon electrodes.

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Reactions in the Rechargeable Lithium–O₂ Battery with Alkyl Carbonate Electrolytes

et al. 2011

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The nonaqueous rechargeable lithium-O(2) battery containing an alkyl carbonate electrolyte discharges by formation of C(3)H(6)(OCO(2)Li)(2), Li(2)CO(3), HCO(2)Li, CH(3)CO(2)Li, CO(2), and H(2)O at the cathode, due to electrolyte decomposition. Charging involves oxidation of C(3)H(6)(OCO(2)Li)(2), Li(2)CO(3), HCO(2)Li, CH(3)CO(2)Li accompanied by CO(2) and H(2)O evolution. Mechanisms are proposed for the reactions on discharge and charge. The different pathways for discharge and charge are consistent with the widely observed voltage gap in Li-O(2) cells. Oxidation of C(3)H(6)(OCO(2)Li)(2) involves terminal carbonate groups leaving behind the OC(3)H(6)O moiety that reacts to form a thick gel on the Li anode. Li(2)CO(3), HCO(2)Li, CH(3)CO(2)Li, and C(3)H(6)(OCO(2)Li)(2) accumulate in the cathode on cycling correlating with capacity fading and cell failure. The latter is compounded by continuous consumption of the electrolyte on each discharge.

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The Lithium–Oxygen Battery with Ether‐Based Electrolytes

et al. 2011

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Yuhui Chen

The role of LiO2 solubility in O2 reduction in aprotic solvents and its consequences for Li–O2 batteries

A Reversible and Higher-Rate Li-O ₂ Battery

Reactions in the Rechargeable Lithium–O₂ Battery with Alkyl Carbonate Electrolytes

The Lithium–Oxygen Battery with Ether‐Based Electrolytes

Contact Info

Product

Resources

About

Yuhui Chen

The role of LiO2 solubility in O2 reduction in aprotic solvents and its consequences for Li–O2 batteries

A Reversible and Higher-Rate Li-O 2 Battery

Reactions in the Rechargeable Lithium–O2 Battery with Alkyl Carbonate Electrolytes

The Lithium–Oxygen Battery with Ether‐Based Electrolytes

Contact Info

Product

Resources

About

A Reversible and Higher-Rate Li-O ₂ Battery

Reactions in the Rechargeable Lithium–O₂ Battery with Alkyl Carbonate Electrolytes