Cycling Li-O-2 batteries via LiOH formation and decomposition

Tao Liu; Michal Leskes; Wanjing Yu; Amy J. Moore; Lina Zhou; Paul M. Bayley; Gunwoo Kim; Clare P. Grey

doi:10.1126/science.aac7730

Cycling Li-O-2 batteries via LiOH formation and decomposition

Tao Liu, Michal Leskes, Wanjing Yu, Amy J. Moore, Lina Zhou, Paul M. Bayley, Gunwoo Kim, Clare P. Grey

Department of Molecular Chemistry and Materials Science Perlman

Weizmann Institute of Science

Research output: Contribution to journal › Article › peer-review

Abstract

The rechargeable aprotic lithium-air (Li-O-2) battery is a promising potential technology for next-generation energy storage, but its practical realization still faces many challenges. In contrast to the standard Li-O-2 cells, which cycle via the formation of Li-2 O-2, we used a reduced graphene oxide electrode, the additive LiI, and the solvent dimethoxyethane to reversibly form and remove crystalline LiOH with particle sizes larger than 15micrometers during discharge and charge. This leads to high specific capacities, excellent energy efficiency (93.2%) with a voltage gap of only 0.2 volt, and impressive rechargeability. The cells tolerate high concentrations of water, water being the dominant proton source for the LiOH; together with LiI, it has a decisive impact on the chemical nature of the discharge product and on battery performance.

Original language	English
Pages (from-to)	530-533
Number of pages	4
Journal	Science
Volume	350
Issue number	6260
DOIs	https://doi.org/10.1126/science.aac7730
State	Published - 30 Oct 2015

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title = "Cycling Li-O-2 batteries via LiOH formation and decomposition",

abstract = "The rechargeable aprotic lithium-air (Li-O-2) battery is a promising potential technology for next-generation energy storage, but its practical realization still faces many challenges. In contrast to the standard Li-O-2 cells, which cycle via the formation of Li-2 O-2, we used a reduced graphene oxide electrode, the additive LiI, and the solvent dimethoxyethane to reversibly form and remove crystalline LiOH with particle sizes larger than 15micrometers during discharge and charge. This leads to high specific capacities, excellent energy efficiency (93.2%) with a voltage gap of only 0.2 volt, and impressive rechargeability. The cells tolerate high concentrations of water, water being the dominant proton source for the LiOH; together with LiI, it has a decisive impact on the chemical nature of the discharge product and on battery performance.",

author = "Tao Liu and Michal Leskes and Wanjing Yu and Moore, {Amy J.} and Lina Zhou and Bayley, {Paul M.} and Gunwoo Kim and Grey, {Clare P.}",

note = "This work was partially supported by the Assistant Secretary for Energy Efficiency and Renewable Energy, Office of Vehicle Technologies of the U.S. Department of Energy, under contract no. DE-AC02-05CH11231, under the Batteries for Advanced Transportation Technologies Program subcontract 7057154 (W.Y., M.J.L., P.M.B.); the Engineering and Physical Sciences Research Council (T.L.); Johnson Matthey (A.M.); Marie Curie Actions (P.M.B. and M.L.); and the EU Graphene Flagship under contract no. 604391 (G.K.). M. T. L. Casford and members of the Cambridge Graphene Centre are thanked for many useful discussions.",

year = "2015",

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doi = "10.1126/science.aac7730",

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TY - JOUR

T1 - Cycling Li-O-2 batteries via LiOH formation and decomposition

AU - Liu, Tao

AU - Leskes, Michal

AU - Yu, Wanjing

AU - Moore, Amy J.

AU - Zhou, Lina

AU - Bayley, Paul M.

AU - Kim, Gunwoo

AU - Grey, Clare P.

N1 - This work was partially supported by the Assistant Secretary for Energy Efficiency and Renewable Energy, Office of Vehicle Technologies of the U.S. Department of Energy, under contract no. DE-AC02-05CH11231, under the Batteries for Advanced Transportation Technologies Program subcontract 7057154 (W.Y., M.J.L., P.M.B.); the Engineering and Physical Sciences Research Council (T.L.); Johnson Matthey (A.M.); Marie Curie Actions (P.M.B. and M.L.); and the EU Graphene Flagship under contract no. 604391 (G.K.). M. T. L. Casford and members of the Cambridge Graphene Centre are thanked for many useful discussions.

PY - 2015/10/30

Y1 - 2015/10/30

N2 - The rechargeable aprotic lithium-air (Li-O-2) battery is a promising potential technology for next-generation energy storage, but its practical realization still faces many challenges. In contrast to the standard Li-O-2 cells, which cycle via the formation of Li-2 O-2, we used a reduced graphene oxide electrode, the additive LiI, and the solvent dimethoxyethane to reversibly form and remove crystalline LiOH with particle sizes larger than 15micrometers during discharge and charge. This leads to high specific capacities, excellent energy efficiency (93.2%) with a voltage gap of only 0.2 volt, and impressive rechargeability. The cells tolerate high concentrations of water, water being the dominant proton source for the LiOH; together with LiI, it has a decisive impact on the chemical nature of the discharge product and on battery performance.

AB - The rechargeable aprotic lithium-air (Li-O-2) battery is a promising potential technology for next-generation energy storage, but its practical realization still faces many challenges. In contrast to the standard Li-O-2 cells, which cycle via the formation of Li-2 O-2, we used a reduced graphene oxide electrode, the additive LiI, and the solvent dimethoxyethane to reversibly form and remove crystalline LiOH with particle sizes larger than 15micrometers during discharge and charge. This leads to high specific capacities, excellent energy efficiency (93.2%) with a voltage gap of only 0.2 volt, and impressive rechargeability. The cells tolerate high concentrations of water, water being the dominant proton source for the LiOH; together with LiI, it has a decisive impact on the chemical nature of the discharge product and on battery performance.

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DO - 10.1126/science.aac7730

M3 - مقالة

SN - 0036-8075

VL - 350

SP - 530

EP - 533

JO - Science

JF - Science

IS - 6260

ER -

Cycling Li-O-2 batteries via LiOH formation and decomposition

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