酶与非酶生物燃料电池的研究进展与展望特别强调二维纳米材料

K. K. Sadasivuni, M. Geetha, Maryam Al-Ejji, Nandagopal Sivadas, M. Z. K. Baig, Tamanna Jannat Promi, Sumayya Ali Ahmad, Sara Alabed, D. Hijazi, Fatimatulzahraa Alsaedi, Faozia Nasser Al-Shaibah
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摘要

可再生能源发电和有效管理是可持续发展面临的两个关键挑战。生物燃料电池(bfc)结合了这两项任务,提供了一种有效的解决方案。BFCs是由燃料电池中使用的催化剂定义的,它可以直接从生物物质中发电。各种无毒化学燃料,如葡萄糖、乳酸盐、尿酸盐、酒精、胺、淀粉和果糖,可用于BFCs,并具有氧化燃料的特定成分。广泛的燃料来源和适中的运行条件使其在可再生能源发电、远程设备电源等方面具有广阔的应用前景。酶生物燃料电池(EBFCs)使用酶作为催化剂来氧化燃料,而不是贵金属。EBFCs系统的缺点导致了集成小型化问题、功率密度低、运行稳定性差、电压输出低、能量密度低、耐久性不足、长期使用不稳定以及燃料氧化不完全。这就需要开发非酶生物燃料电池(nebfc)。综述了NEBFCs及其各种合成策略和催化特性。本文综述了纳米复合材料作为生物催化剂在生物燃料电池中的应用,以及生物燃料电池的原理和构成要素。本文简要介绍了近年来改善BFCs生物催化性能、生物相容性、生物降解性、可移植性和机械柔韧性的技术进展。
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Review of Progress and Prospects in Research on Enzymatic and Non-Enzymatic Biofuel Cells; Specific Emphasis on 2D Nanomaterials
Energy generation from renewable sources and effective management are two critical challenges for sustainable development. Biofuel Cells (BFCs) provide an effectice solution by combining these two tasks. BFCs are defined by the catalyst used in the fuel cell and can directly generate electricity from biological substances. Various nontoxic chemical fuels, such as glucose, lactate, urate, alcohol, amines, starch, and fructose, can be used in BFCs and have specific components to oxide fuels. Widely available fuel sources and moderate operational conditions make them promise in renewable energy generation, remote device power sources, etc. Enzymatic biofuel cells (EBFCs) use enzymes as a catalyst to oxidize the fuel rather than precious metals. The shortcoming of the EBFCs system leads to integrated miniaturization issues, lower power density, poor operational stability, lower voltage output, lower energy density, inadequate durability, instability in the long-term application, and incomplete fuel oxidation. This necessitates the development of non-enzymatic biofuel cells (NEBFCs). The review paper extensively studies NEBFCs and its various synthetic strategies and catalytic characteristics. This paper reviews the use of nanocomposites as biocatalysts in biofuel cells and the principle of biofuel cells as well as their construction elements. This review briefly presents recent technologies developed to improve the biocatalytic properties, biocompatibility, biodegradability, implantability, and mechanical flexibility of BFCs.
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