Bioelectricity generation and anodic decolorization of reactive dyes in H-type microbial fuel cell using Pseudomonas gessardii

IF 9 Q1 ENVIRONMENTAL SCIENCES Environmental Chemistry and Ecotoxicology Pub Date : 2024-01-01 DOI:10.1016/j.enceco.2024.06.003
Roma Agrahari , Sangita Karmakar , Radha Rani
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Abstract

Anodic decolorization of reactive dyes like Coomassie Brilliant Blue (CB), a triphenylmethane dye, Reactive Red 120 (RR 120) and Reactive Black 5 (RB 5), azo dyes, was investigated in a 300-ml H-type dual chamber Microbial Fuel Cell (MFC) using monoculture of a novel strain Pseudomonas gessardii DD1. The MFC setups were evaluated for power generation, electrochemical activity, dye decolorizing efficiency, and COD removal efficiency. The study revealed a maximum power density 474.06 mW/m2 for RB 5 at 100 ppm concentration with 98.5% dye decolorization, while the maximum COD removal efficiency of 70% ± 2.9 was obtained. Cyclic voltammetry curves indicated the highest peak current of 1.8 mA for MFC operated using RB5. Maximum power density, in case of RR 120 and CB was 262.5 and 225.5 mW/m2, with 63 and 65% COD removal, respectively. Efficient power generation and dye removal is seldom reported in the literature, as the electrons generated by exoelectrogens are consumed for dye reduction and subsequent breakdown or decolorization. The findings indicate that the MFC technology can be an easy and economical option for bioelectricity generation using dye-contaminated wastewater with simultaneous detoxification of toxic pollutants and hence sustainable treatment of industrial wastewater.

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利用格萨德假单胞菌在 H 型微生物燃料电池中产生生物电并阳极脱色活性染料
在一个 300 毫升的 H 型双室微生物燃料电池(MFC)中,使用新型菌株 Pseudomonas gessardii DD1 单培养,研究了活性染料(如三苯基甲烷染料库马西亮蓝(CB)、偶氮染料反应红 120(RR 120)和反应黑 5(RB 5))的阳极脱色。对 MFC 设置的发电量、电化学活性、染料脱色效率和 COD 去除效率进行了评估。研究表明,在浓度为 100 ppm 的 RB 5 中,最大功率密度为 474.06 mW/m2,染料脱色率为 98.5%,而 COD 去除效率最高为 70% ± 2.9。循环伏安曲线显示,使用 RB5 运行的 MFC 的最高峰值电流为 1.8 mA。RR 120 和 CB 的最大功率密度分别为 262.5 和 225.5 mW/m2,COD 去除率分别为 63% 和 65%。文献中很少有关于高效发电和去除染料的报道,因为外电荷产生的电子被用于染料还原和随后的分解或脱色。研究结果表明,MFC 技术是利用被染料污染的废水进行生物发电的一种简单而经济的选择,同时还能对有毒污染物进行解毒,从而实现工业废水的可持续处理。
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