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Integrated Bifunctional Oxygen Electrodes for Flexible Zinc–Air Batteries: From Electrode Designing to Wearable Energy Storage

The strong propulsion stem from flexible/wearable electronics has greatly stimulated the development of miniaturized and high‐performance rechargeable batteries with adaptable shape. Flexible zinc–air batteries (FZABs), which exhibit high theoretical energy density (1218 Wh kg−1), low cost, environm...

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Published in:Advanced materials technologies 2022-01, Vol.7 (1), p.n/a
Main Authors: Yang, Xuhuan, Li, Simeng, Ye, Dewei, Kuang, Jiaqi, Guo, Shu, Zou, Yueyuan, Cai, Xin
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Language:English
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cited_by cdi_FETCH-LOGICAL-c3553-be888f58f7a58f05339058d0cab6c7698fc7c1aa0e7e3f10919faabe894226813
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container_title Advanced materials technologies
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description The strong propulsion stem from flexible/wearable electronics has greatly stimulated the development of miniaturized and high‐performance rechargeable batteries with adaptable shape. Flexible zinc–air batteries (FZABs), which exhibit high theoretical energy density (1218 Wh kg−1), low cost, environmental benignancy, and admirable operational safety, have been widely recognized as one of the promising portable powers to serve future wearable electronics for ubiquitous application. During the past five years, the energy/power density and cycling stability of FZABs have gained significant improvement largely due to the rational construction of high‐efficiency bifunctional air electrodes. Herein, the recent progress of integrated binder‐free bifunctional oxygen electrodes is overviewed via elaborate in situ preparation and interface engineering for FZABs. In particular, fiber/cable‐type ZABs with unrivaled omnidirectional‐flexibility and unique knittability are highlighted in virtue of their enormous potential to realize wearable batteries and smart fabrics. From a practical point of view, the recently proposed rechargeable ZABs for integrated/hybridized devices or self‐powered energy systems are reviewed. Finally, the remained challenges and some insightful directions for the future development of high‐performance FZABs are illustrated in the pursuit of cost‐efficient portable powers and multifunctional flexible/wearable electronic devices. Flexible zinc–air batteries (FZABs) are recognized as promising portable powers to serve wearable electronics for ubiquitous application. In the past five years, FZABs have gained significant improvement due to the rational construction of high‐efficiency bifunctional oxygen electrodes. Recent progress of integrated bifunctional cathodes for FZABs, including planar‐structured FZABs, fiber/cable‐type ZABs, and rechargeable ZABs for self‐powered/integrated energy systems are overviewed and highlighted.
doi_str_mv 10.1002/admt.202100673
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subjects bifunctional oxygen electrocatalysts
binder‐free oxygen electrodes
fiber batteries
flexible zinc–air batteries
self‐powered energy systems
wearable electronics
title Integrated Bifunctional Oxygen Electrodes for Flexible Zinc–Air Batteries: From Electrode Designing to Wearable Energy Storage
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