生物阴极的电化作用调节单室系统中 CO 微生物电化学转化为脂肪酸。

Electrotrophy of biocathodes regulates microbial-electro-catalyzation of CO to fatty acids in single chambered system.

机构信息

Bioengineering and Environmental Sciences Lab, Department of Energy and Environmental Engineering (DEEE), CSIR-Indian Institute of Chemical Technology (CSIR-IICT), Hyderabad 500007, India.

出版信息

Bioresour Technol. 2021 Jan;320(Pt A):124272. doi: 10.1016/j.biortech.2020.124272. Epub 2020 Oct 16.

DOI:10.1016/j.biortech.2020.124272

PMID:33142252

Abstract

Microbial electrochemical conversion of CO to value-added products needs effectual biocathodes. In this study, three different working electrodes (biocathode) namely carbon cloth (CC, MES1), stainless steel mesh (SS, MES2) and hybrid electrode (CC + SS, MES3) were evaluated in membrane-less single-chambered Microbial electrosynthesis systems (MESs). Performance of MES was assessed by total volatile fatty acids (VFA) productivity and, reductive current generations upon continuous poised potential (-0.4 V vs. Ag/AgCl (3.5 M KCl)). MES3 showed higher VFA synthesis (CC + SS; 1.4 g VFA/L), followed by MES1 (CC; 1.1 g VFA/L) and MES2 (SS; 0.8 g VFA/L) with corresponding reductive current generation of -1.13 mA, -2.74 mA and -0.39 mA. Electro-kinetics revealed the biocathode efficacy towards enhanced electrotrophy with confined electron losses by regulating electron flux in the system. The study infers the potential of hybrid electrode as an efficient biocathode for the reduction of CO to VFA synthesis.

摘要

微生物电化学将 CO 转化为增值产品需要有效的生物阴极。在这项研究中，三种不同的工作电极（生物阴极），即碳纤维布（CC，MES1）、不锈钢网（SS，MES2）和混合电极（CC+SS，MES3），在无膜单室微生物电化学合成系统（MESs）中进行了评估。通过连续恒电位（-0.4 V 相对于 Ag/AgCl（3.5 M KCl））下的总挥发性脂肪酸（VFA）生产力和还原电流生成来评估 MES 的性能。MES3 显示出更高的 VFA 合成（CC+SS；1.4 g VFA/L），其次是 MES1（CC；1.1 g VFA/L）和 MES2（SS；0.8 g VFA/L），相应的还原电流生成分别为-1.13 mA、-2.74 mA 和-0.39 mA。电化学动力学表明，通过调节系统中的电子通量，生物阴极对增强的电营养具有效力，可以限制电子损失。该研究推断，混合电极作为一种有效的生物阴极，具有将 CO 还原为 VFA 合成的潜力。

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生物阴极的电化作用调节单室系统中 CO 微生物电化学转化为脂肪酸。

Electrotrophy of biocathodes regulates microbial-electro-catalyzation of CO to fatty acids in single chambered system.

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