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Angewandte Chemie, 2019
Flexible Li-air battery (FLAB) with ultrahigh energy density is a hopeful candidate for the forthcoming flexible energy storage devices. However, most current FLAB operated in the pure oxygen atmosphere which limited by the safety and corrosion issues ...
Yu Zhang
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Flexible Li-air battery (FLAB) with ultrahigh energy density is a hopeful candidate for the forthcoming flexible energy storage devices. However, most current FLAB operated in the pure oxygen atmosphere which limited by the safety and corrosion issues ...
Yu Zhang
semanticscholar +1 more source
Metal–air batteries for powering robots
Journal of Materials Chemistry A, 2023By investigating the technological development of metal–air batteries in terms of specific energy, cycle life, fast charging, environmental adaptability and flexibility, we propose the application of metal–air batteries for powering robotic devices.
Daiyuan Zhong +9 more
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Engineering Triple‐Phase Interfaces around the Anode toward Practical Alkali Metal–Air Batteries
Advances in MaterialsAlkali metal–air batteries (AMABs) promise ultrahigh gravimetric energy densities, while the inherent poor cycle stability hinders their practical application.
Bingcheng Ge +7 more
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Microstructure design of advanced magnesium-air battery anodes
Journal of Magnesium and AlloysMetal-air battery is an environmental friendly energy storage system with unique open structure. Magnesium (Mg) and its alloys have been extensively attempted as anodes for air batteries due to high theoretical energy density, low cost, and recyclability.
Xueting Huang +6 more
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ACS Applied Materials and Interfaces, 2018
Clarifying and controlling the surface catalytic active sites is at the heart of developing low-cost effective bifunctional oxygen catalysts to replace precious metals for metal-air batteries. Herein, a shape-control of hexagon nickel cobalt oxide spinel
Jun Zhao +8 more
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Clarifying and controlling the surface catalytic active sites is at the heart of developing low-cost effective bifunctional oxygen catalysts to replace precious metals for metal-air batteries. Herein, a shape-control of hexagon nickel cobalt oxide spinel
Jun Zhao +8 more
semanticscholar +1 more source
Catalysts in metal-air batteries
MRS Communications, 2018Metal-air batteries promise higher energy densities than state-of-the-art Li-ion batteries and have, therefore, received significant research attention lately. The most distinguishing feature of this technology is that it takes advantage of reversible conversion reactions of O2 or other air components (such as N2 or CO2) at the cathode.
Qi Dong, Dunwei Wang
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ACS Applied Materials and Interfaces, 2017
Efficient bifunctional electrocatalysts with desirable oxygen activities are closely related to practical applications of renewable energy systems including metal-air batteries, fuel cells, and water splitting.
Mengfan Wang +3 more
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Efficient bifunctional electrocatalysts with desirable oxygen activities are closely related to practical applications of renewable energy systems including metal-air batteries, fuel cells, and water splitting.
Mengfan Wang +3 more
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Nanostructured arrays for metal–ion battery and metal–air battery applications
, 2021Da Zhang +4 more
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Metal-Air Battery-Powered Lamp
Metal-air batteries have been a blooming topic in the portable energy industry. This energy source uses thebasic principle of a galvanic cell to create a current. Various metals have been tested, but aluminium metal with apotassium hydroxide solvent (KOH) is the most efficient at producing power. The benefits of a metal-air battery lie in itsproductionAmran Azmi +4 more
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