Benchmarking Power Generation From Multiple Wastewater Electrolytes in Microbial Fuel Cells With 3D Printed Disk-Electrodes

IF 3.7 4区生物学 Q1 BIOCHEMICAL RESEARCH METHODS IEEE Transactions on NanoBioscience Pub Date : 2024-04-08 DOI:10.1109/TNB.2024.3385739

Yuvraj Maphrio Mao;Khairunnisa Amreen;Sanket Goel

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Abstract

Microbial Fuel Cells (MFCs) have recently gained attention, as they are inexpensive, green in nature, and sustainable. As per the report, by Allied Market Research the global market size of MFCs will increase from

${\$}$

264.8 million in 2021 to

${\$}$

452.2 million in 2030, growing at a CAGR of 4.5%. The present work is a comparative study of various types of electrolytes that can be used in MFCs. The working electrodes were printed using conducting graphene-based Polylactic Acid (PLA) filaments with the help of a 3D printer under the principle of the fused deposition method. Simulated electrolytes and natural environmental microbial electrolytes were used here. Also, electrolytes of pure E. coli culture were studied. Lake water reported the highest power density of 8.259 mW/cm2 while Stale E. Coli reported the lowest around 0.184 mW/cm2. The study comprehensively lists potential wastewaters that can fuel the MFCs. With the pioneering of various comparative studies of electrolytes, one can insight into the recruitment of electrolytes with high-performance benchmarks for miniaturized energy storage and other microelectronics applications.

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微生物燃料电池中多种废水电解质的发电基准与 3D 打印磁盘电极

微生物燃料电池（MFCs）因其价格低廉、绿色环保和可持续发展的特性，最近备受关注。根据 Allied Market Research 的报告，MFCs 的全球市场规模将从 2021 年的 2.648 亿美元增至 2030 年的 4.522 亿美元，年复合增长率为 4.5%。本研究对可用于 MFC 的各类电解质进行了比较研究。在熔融沉积法原理的帮助下，使用基于导电石墨烯的聚乳酸（PLA）长丝在三维打印机上打印了工作电极。这里使用了模拟电解质和天然环境微生物电解质。此外，还研究了纯大肠杆菌培养物的电解质。湖水的功率密度最高，为 8.259 mW/cm2，而陈腐大肠杆菌的功率密度最低，约为 0.184 mW/cm2。该研究全面列出了可为 MFCs 提供燃料的潜在废水。随着各种电解质比较研究的开展，人们可以深入了解如何为微型化能源存储和其他微电子应用招募具有高性能基准的电解质。

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来源期刊

IEEE Transactions on NanoBioscience 工程技术-纳米科技

CiteScore

7.00

自引率

5.10%

发文量

197

审稿时长

>12 weeks

期刊介绍： The IEEE Transactions on NanoBioscience reports on original, innovative and interdisciplinary work on all aspects of molecular systems, cellular systems, and tissues (including molecular electronics). Topics covered in the journal focus on a broad spectrum of aspects, both on foundations and on applications. Specifically, methods and techniques, experimental aspects, design and implementation, instrumentation and laboratory equipment, clinical aspects, hardware and software data acquisition and analysis and computer based modelling are covered (based on traditional or high performance computing - parallel computers or computer networks).

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