Literature DB >> 26516278

Cycling Li-O₂ batteries via LiOH formation and decomposition.

Tao Liu1, Michal Leskes1, Wanjing Yu2, Amy J Moore1, Lina Zhou1, Paul M Bayley1, Gunwoo Kim2, Clare P Grey1.   

Abstract

The rechargeable aprotic lithium-air (Li-O2) 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-O2 cells, which cycle via the formation of Li2O2, 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 15 micrometers 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.
Copyright © 2015, American Association for the Advancement of Science.

Entities:  

Year:  2015        PMID: 26516278     DOI: 10.1126/science.aac7730

Source DB:  PubMed          Journal:  Science        ISSN: 0036-8075            Impact factor:   47.728


  24 in total

Review 1.  Sustainability and in situ monitoring in battery development.

Authors:  C P Grey; J M Tarascon
Journal:  Nat Mater       Date:  2016-12-20       Impact factor: 43.841

Review 2.  Redox mediators for high-performance lithium-oxygen batteries.

Authors:  Yaying Dou; Zhaojun Xie; Yingjin Wei; Zhangquan Peng; Zhen Zhou
Journal:  Natl Sci Rev       Date:  2022-03-04       Impact factor: 23.178

Review 3.  Advances in Lithium-Oxygen Batteries Based on Lithium Hydroxide Formation and Decomposition.

Authors:  Xiahui Zhang; Panpan Dong; Min-Kyu Song
Journal:  Front Chem       Date:  2022-07-01       Impact factor: 5.545

4.  High-capacity rechargeable batteries based on deeply cyclable lithium metal anodes.

Authors:  Qiuwei Shi; Yiren Zhong; Min Wu; Hongzhi Wang; Hailiang Wang
Journal:  Proc Natl Acad Sci U S A       Date:  2018-05-14       Impact factor: 11.205

Review 5.  Why Do Lithium-Oxygen Batteries Fail: Parasitic Chemical Reactions and Their Synergistic Effect.

Authors:  Xiahui Yao; Qi Dong; Qingmei Cheng; Dunwei Wang
Journal:  Angew Chem Int Ed Engl       Date:  2016-07-06       Impact factor: 15.336

6.  Mechanism and performance of lithium-oxygen batteries - a perspective.

Authors:  Nika Mahne; Olivier Fontaine; Musthafa Ottakam Thotiyl; Martin Wilkening; Stefan A Freunberger
Journal:  Chem Sci       Date:  2017-07-31       Impact factor: 9.825

7.  Carbon nanotube/Co3O4 nanocomposites selectively coated by polyaniline for high performance air electrodes.

Authors:  Jin Young Kim; Yong Joon Park
Journal:  Sci Rep       Date:  2017-08-17       Impact factor: 4.379

8.  Oxygen-Rich Lithium Oxide Phases Formed at High Pressure for Potential Lithium-Air Battery Electrode.

Authors:  Wenge Yang; Duck Young Kim; Liuxiang Yang; Nana Li; Lingyun Tang; Khalil Amine; Ho-Kwang Mao
Journal:  Adv Sci (Weinh)       Date:  2017-05-19       Impact factor: 16.806

9.  Organic hydrogen peroxide-driven low charge potentials for high-performance lithium-oxygen batteries with carbon cathodes.

Authors:  Shichao Wu; Yu Qiao; Sixie Yang; Masayoshi Ishida; Ping He; Haoshen Zhou
Journal:  Nat Commun       Date:  2017-06-06       Impact factor: 14.919

10.  Electrocatalytic performances of g-C3N4-LaNiO3 composite as bi-functional catalysts for lithium-oxygen batteries.

Authors:  Yixin Wu; Taohuan Wang; Yidie Zhang; Sen Xin; Xiaojun He; Dawei Zhang; Jianglan Shui
Journal:  Sci Rep       Date:  2016-04-14       Impact factor: 4.379
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