Soil Microbial Fuel Cell with Hydrophilic Treated Buckypaper Anodes

Proceeding of Science and Technology Pub Date : 2023-09-30 DOI:10.21625/resourceedings.v3i2.998

Soichiro Hirose, Trang Nakamoto, Kozo Taguchi

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Abstract

Fossil fuels, the primary source of energy supply in modern society, are both unsustainable and damaging to the environment. The most cost-effective way to reduce the use of fossil fuels is to switch to renewable energy sources. Soil microbial fuel cells (SMFC) are a green energy production method because they use electron-generating bacteria in the soil to obtain electrical energy from organic matter. One way to improve the output of SMFCs is to increase the specific surface area of the anodes. The larger specific surface area allows more electrons to be received from the bacteria. In this study, bucky paper (BP) was utilized as the anode of SMFC. BP is a freestanding film fabricated from multi-walled carbon nanotubes (CNT) by vacuum filtration method. CNT has a high specific surface area and electrical conductivity. BP is also considered to be mechanically stable in soil due to its CNT network structure. However, the surface of the BP is hydrophobic. In SMFCs, the hydrophobic surface of the anode is a fatal disadvantage in terms of the affinity of microorganisms. Thus, heat treatment and UV ozone treatment were employed to make the surface of BP hydrophilic, and their output in SMFCs was investigated. As a result, SMFCs using UV-ozone-treated BPs as anodes produced the highest power density of 28.8 μW/cm². Also, unlike thermal treatment, UV ozone treatment did not damage the CNT structure. Hence, in this experiment, the output power of the SMFC was stable for at least 140 hours.

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土壤微生物燃料电池与亲水性处理巴克纸阳极

化石燃料是现代社会能源供应的主要来源，既不可持续又对环境有害。减少化石燃料使用的最具成本效益的方法是转向可再生能源。土壤微生物燃料电池(SMFC)是一种绿色能源生产方法，它利用土壤中产生电子的细菌从有机物中获取电能。提高smfc输出的一种方法是增加阳极的比表面积。更大的比表面积允许更多的电子从细菌接收。本研究采用巴基纸(BP)作为SMFC阳极。BP是一种由多壁碳纳米管(CNT)通过真空过滤法制备的独立薄膜。碳纳米管具有很高的比表面积和导电性。由于其碳纳米管网络结构，BP也被认为在土壤中具有机械稳定性。然而，BP的表面是疏水的。在smfc中，阳极的疏水表面对微生物的亲和力是一个致命的缺点。因此，采用热处理和紫外臭氧处理使BP表面亲水，并研究了它们在smfc中的产量。结果表明，使用uv -臭氧处理的bp作为阳极的smfc产生的功率密度最高，为28.8 μW/cm²。此外，与热处理不同，紫外线臭氧处理不会破坏碳纳米管的结构。因此，在本实验中，SMFC的输出功率至少稳定140小时。

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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Proceeding of Science and Technology

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