Compressible Zn–Air Batteries Based on Metal–Organic Frameworks Nanoflake‐Assembled Carbon Frameworks for Portable Motion and Temperature Monitors

High‐performance and integrated power sources are critical to the practical application of wearable sensors, enabling monitoring of physical signs in real time. However, realizing both good battery performance and portability for batteries is still a challenge to such integration application. Herein...

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Bibliographic Details
Published in:Advanced energy and sustainability research 2022-07, Vol.3 (7), p.n/a
Main Authors: Zheng, Dong, Liu, Wenxian, Dai, Xiaojing, Feng, Jinxiu, Xu, Xilian, Yin, Ruilian, Que, Wenbin, Shi, Wenhui, Wu, Fangfang, Wu, Huaping, Cao, Xiehong
Format: Article
Language:English
Subjects:
Air temperature
Carbon
Carbon sources
Cathodes
Chemical reduction
Compressibility
Deformation
Electrode materials
Electrodes
Energy storage
Flexibility
Flexible components
flexible Zn–air batteries
Fourier transforms
Graphene
Humidity
Integration
Intermetallic compounds
Iron compounds
Metal air batteries
Metal-organic frameworks
Nickel compounds
Nitrogen
oxygen evolution reaction
Power management
Power sources
Power supply
Scanning electron microscopy
Sensors
Specific capacity
Spectrum analysis
strain-responsive devices
Two dimensional materials
wearable devices
Zinc-oxygen batteries
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Summary:High‐performance and integrated power sources are critical to the practical application of wearable sensors, enabling monitoring of physical signs in real time. However, realizing both good battery performance and portability for batteries is still a challenge to such integration application. Herein, a novel cathode material of flexible zinc–air battery is developed, i.e., NiFe‐based metal–organic frameworks nanoflakes assembled on the carbon frameworks with nitrogen‐heteroatom dopant (NiFe NF/NCFs). Benefiting from the unique interfacial interaction of 2D materials, as well as the rational integration of multifunctional electrocatalytic components in a flexible and compressible skeleton, the prepared NiFe NF/NCFs exhibits excellent activities for oxygen evolution/reduction reactions. Moreover, it achieves high peak power density (107.2 mW cm−2) and specific capacity (814.2 mAh g−1) when served as the cathode of zinc–air batteries. Importantly, serving as both battery cathode and sensing unit, a strain sensor–battery integration device is also demonstrated based on the NiFe NF/NCFs, which displays a favorable strain sensitivity toward detecting human motions. This work provides a new pathway to the development of energy storage device for flexible electronics. NiFe metal–organic frameworks nanoflake‐assembled nitrogen‐doped carbon frameworks (NiFe NF/NCFs) are reported and serve as electrode for both flexible Zn–air batteries (FZAB) and strain sensor–battery integration devices. The FZAB delivers high peak power density (107.2 mW cm−2), and specific capacity (814.2 mAh g−1). Moreover, a favorable strain sensitivity towards detecting human motions is demonstrated in a strain sensor–battery integration device.
ISSN:2699-9412
2699-9412
DOI:10.1002/aesr.202200014