Enhancement of Biogas (Methane) Production from Cow Dung Using a Microbial Electrochemical Cell and Molecular Characterization of Isolated Methanogenic Bacteria

Biomass Pub Date : 2024-05-23 DOI:10.3390/biomass4020023

Puja Bhatt, Pranita Poudyal, Pradip Dhungana, Bikram Prajapati, Suman Bajracharya, Amar Prasad Yadav, T. Bhattarai, L. Sreerama, Jarina Joshi

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Abstract

Biogas has long been used as a household cooking fuel in many tropical counties, and it has the potential to be a significant energy source beyond household cooking fuel. In this study, we describe the use of low electrical energy input in an anaerobic digestion process using a microbial electrochemical cell (MEC) to promote methane content in biogas at 18, 28, and 37 °C. Although the maximum amount of biogas production was at 37 °C (25 cm3), biogas could be effectively produced at lower temperatures, i.e., 18 (13 cm3) and 28 °C (19 cm3), with an external 2 V power input. The biogas production of 13 cm3 obtained at 18 °C was ~65-fold higher than the biogas produced without an external power supply (0.2 cm3). This was further enhanced by 23% using carbon-nanotubes-treated (CNT) graphite electrodes. This suggests that the MEC can be operated at as low as 18 °C and still produce significant amounts of biogas. The share of CH4 in biogas produced in the controls was 30%, whereas the biogas produced in an MEC had 80% CH4. The MEC effectively reduced COD to 42%, whereas it consumed 98% of reducing sugars. Accordingly, it is a suitable method for waste/manure treatment. Molecular characterization using 16s rRNA sequencing confirmed the presence of methanogenic bacteria, viz., Serratia liquefaciens and Zoballella taiwanensis, in the inoculum used for the fermentation. Consistent with recent studies, we believe that electromethanogenesis will play a significant role in the production of value-added products and improve the management of waste by converting it to energy.

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利用微生物电化学电池提高牛粪中的沼气（甲烷）产量以及分离出的产甲烷细菌的分子特征描述

在许多热带国家，沼气长期以来一直被用作家庭烹饪燃料，它有可能成为家庭烹饪燃料之外的重要能源。在这项研究中，我们介绍了在厌氧消化过程中使用微生物电化学电池（MEC），在 18、28 和 37 °C温度下使用低电能输入来提高沼气中的甲烷含量。虽然 37 ℃（25 cm3）时沼气产量最大，但在较低温度下，即 18 ℃（13 cm3）和 28 ℃（19 cm3），通过外部 2 V 电源输入，也能有效地产生沼气。在 18 °C 时产生的 13 立方厘米沼气比不使用外部电源时产生的沼气（0.2 立方厘米）高出约 65 倍。使用碳纳米管处理过的石墨电极，沼气产量进一步提高了 23%。这表明，MEC 可在低至 18 °C 的温度下运行，并仍能产生大量沼气。对照组产生的沼气中 CH4 所占比例为 30%，而 MEC 产生的沼气中 CH4 所占比例为 80%。MEC 能有效地将 COD 降低到 42%，而消耗的还原糖却高达 98%。因此，这是一种适用于废物/粪便处理的方法。利用 16s rRNA 测序进行的分子鉴定证实，发酵所用的接种物中存在产甲烷菌，即液化沙雷氏菌和台湾藻菌。与最近的研究一致，我们相信电生甲烷将在生产增值产品方面发挥重要作用，并通过将废物转化为能源改善废物管理。

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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Biomass

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