Tissue-derived highly compressible anisotropic carbon aerogels with aligned fibrous matrices for solid-state rechargeable zinc-cobalt-air hybrid batteries

IF 10.7 Q1 CHEMISTRY, PHYSICAL EcoMat Pub Date : 2023-12-12 DOI:10.1002/eom2.12431

Ye-Eun Park, Seung-Hee Park, Sung Hoon Ahn

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Abstract

The rising demand for wearable zinc-air batteries encounters challenges in balancing electrochemical performance and mechanical resilience. Elastic carbon aerogels in air cathodes necessitate a metal content constraint of less than 3 wt.%, adversely impacting catalytic activity optimization. This study presents a novel fabrication method for fibrous carbon aerogels with high compressive resilience and extraordinary catalytic performance. An external layer of graphene shells and carbon nanotubes integrated onto the fibrous carbon matrix mitigates metallic species diffusion. This confinement ensures exceptional bi-catalytic activity for oxygen-involved redox reactions without compromising ultra-elasticity. With high cobalt content in the aerogel cathode, it exhibits minimal voltage gaps during charge–discharge cycles, showcasing unique zinc-cobalt-air hybrid battery characteristics. It sustains exceptional elasticity in repeated testing, achieving approximately 79.2% round-trip efficiency over a 60-h cycle test, underscoring its potential as a wearable energy storage device.

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用于固态可充电锌-钴-空气混合电池的组织衍生型高可压缩各向异性碳气凝胶与排列整齐的纤维基质

可穿戴锌-空气电池的需求不断增长，但在平衡电化学性能和机械弹性方面却遇到了挑战。空气阴极中的弹性碳气凝胶的金属含量必须小于 3 wt.%，这对催化活性的优化产生了不利影响。本研究提出了一种新颖的纤维状碳气凝胶制造方法，这种气凝胶具有很高的抗压回弹性和非凡的催化性能。在纤维状碳基质上集成了石墨烯壳和碳纳米管外层，可减轻金属物种的扩散。这种限制确保了在不影响超弹性的情况下，对与氧有关的氧化还原反应具有卓越的双催化活性。由于气凝胶阴极中的钴含量较高，因此在充放电循环过程中电压间隙极小，显示出独特的锌-钴-空气混合电池特性。它在反复测试中保持了超强的弹性，在 60 小时的循环测试中实现了约 79.2% 的往返效率，突出了其作为可穿戴储能设备的潜力。

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来源期刊

EcoMat

CiteScore

17.30

自引率

0.00%

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审稿时长

4 weeks