Cobalt valence modulating in CoOx incorporated carbon nanofiber for enhanced glucose electrooxidation

Jiadong Hu, Hao Lu, Mingsong Li, Gang Xiao, Min Li, Xuemei Xiang, Zhisong Lu, Yan Qiao
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引用次数: 5

Abstract

Glucose fuel cells (GFCs) driven by abiotic catalysts are promising green power sources for portable or wearable devices. In this work, a CoOx incorporated carbon nanofiber (CoOx@CNF) catalyst with mixed valences cobalt oxides have been developed through partial oxidation of pyrolyzed electrospun Co2+/poly acrylonitrile fibers. The cobalt valence modulating could be achieved via regulating the incorporation ratio of cobalt acetate in precursors or the oxidation temperature of the pyrolyzed fibers. Electrocatalytic analyses show that the presence of CoO in CoOx@CNF will provide more active sites for glucose electrooxidation, and thus enhance the electrocatalytic performance significantly. As a result, the glucose fuel cell built with the CoOx@CNF anode containing both CoO and Co3O4 delivered a maximum power density of 270 μW cm−2, which is higher than that of other reported Co3O4 based GFCs. This work provides a simple strategy to develop excellent transition metal catalysts for GFCs to expand their applications in portable and wearable energy devices.

Abstract Image

CoOx掺入碳纳米纤维中钴价态的调节用于增强葡萄糖电氧化
由非生物催化剂驱动的葡萄糖燃料电池(GFCs)是便携式或可穿戴设备的有前途的绿色电源。在这项工作中,一种掺入CoOx的碳纳米纤维(CoOx@CNF)以电纺Co2+/丙烯腈纤维为原料,通过部分氧化制备了混合价钴氧化物催化剂。钴价态调节可以通过调节乙酸钴在前体中的掺入比例或热解纤维的氧化温度来实现。电催化分析表明CoOx@CNF将为葡萄糖的电氧化提供更多的活性位点,从而显著提高电催化性能。因此,用CoOx@CNF同时含有CoO和Co3O4的阳极提供了270μW cm−2的最大功率密度,这高于其他报道的基于Co3O4基的GFCs。这项工作提供了一种简单的策略来开发用于GFCs的优秀过渡金属催化剂,以扩大其在便携式和可穿戴能源设备中的应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
材料导报:能源(英文)
材料导报:能源(英文) Renewable Energy, Sustainability and the Environment, Nanotechnology
CiteScore
13.00
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0.00%
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50 days
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