Determination of optimal operating conditions for bioelectrolyte fuel cells using ADH as anode catalyst and solidification of fuel

IF 3.8 Q2 CHEMISTRY, PHYSICAL Chemical Physics Impact Pub Date : 2024-08-12 DOI:10.1016/j.chphi.2024.100709

Yusuke Takahashi, Hitoki Semizo, Yasumitsu Matsuo

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Abstract

Enzyme-based direct ethanol fuel cells (DEFCs) have the potential to become the next generation of energy devices without platinum catalysts. However, the development of DEFCs requires the search for new electrolytes that are compatible with ethanol fuel and enzymes. In this study, DEFCs with a combination of chitin electrolytes and ADH were fabricated and characterized. DEFCs using chitin electrolyte were also investigated for various ethanol fuel concentrations, and it was found that DEFCs using 50 mM ethanol achieved the highest power density. In addition, enzyme activity was measured and showed a maximum value when 50 mM ethanol was used, suggesting that the proton production reaction catalyzed by the enzyme determines the maximum power density of the bioelectrolyte DEFC. Furthermore, we successfully fabricated a highly portable solid bio-electrolyte DEFC and found that it achieved a maximum power density of 0.11 mW/cm² at an ethanol concentration of 25 %.

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确定使用 ADH 作为阳极催化剂和燃料固化的生物电解质燃料电池的最佳运行条件

基于酶的直接乙醇燃料电池（DEFCs）有可能成为下一代不使用铂催化剂的能源设备。然而，开发直接乙醇燃料电池需要寻找与乙醇燃料和酶兼容的新电解质。本研究制作并表征了甲壳素电解质与 ADH 组合的 DEFCs。使用甲壳素电解质的 DEFCs 还针对不同浓度的乙醇燃料进行了研究，结果发现使用 50 mM 乙醇的 DEFCs 功率密度最高。此外，我们还测量了酶的活性，结果表明当使用 50 mM 乙醇时，酶的活性达到最大值，这表明酶催化的质子生成反应决定了生物电解质 DEFC 的最大功率密度。此外，我们还成功制造了一种高度便携的固体生物电解质 DEFC，并发现在乙醇浓度为 25% 时，它的最大功率密度为 0.11 mW/cm2。

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