Effect of Corncob Derived Biochar on Microbial Electroremediation of Dye Wastewater and Bioenergy Generation

Sonu, Kumar; Sogani, Monika; Syed, Zainab; Dongre, Aman; Sharma, Garima

doi:10.1002/slct.202002652

Cited by 20 publications

(7 citation statements)

References 32 publications

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“…The current and power densities were divided by the predicted anode surface area to get the current and power densities. All MFC tests were carried out in triplicate, and average data were given (Sonu et al 2020).…”

Section: Electrochemical Calculationsmentioning

confidence: 99%

Ultrasonic pre-treatment of Bacillus velezensis for improved electrogenic response in a single chambered microbial fuel cell

et al. 2021

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Various microbial strains and techniques are being used to improve power production in microbial fuel cells. Cow dung is a peculiar source of anaerobic and micro-aerophilic organisms that were employed in this study to isolate exo-electrogenic microorganisms. To validate their exo-electrogenic nature, all eight visually distinct bacterial single-cell colonies were tested using the ferrocyanide reduction assay, which resulted in the selection of one bacterial strain AD1-ELB with the ability to reduce ferrocyanide for further biochemical, physiological and electrochemical characterization. The selected strain AD1-ELB was identified as Bacillus velezensis by 16 s rRNA gene sequencing. When used in a single-chambered MFC, the isolated AD1-ELB strain produced a maximum open-circuit voltage of 455 mV with a maximum current density of 51.78 µA/cm 2 and maximum power density of 4.33 µW/cm 2 on the 16th day. Bacillus velezensis AD1-ELB strain was treated with lowfrequency ultrasound (40 kHz) for 1, 2, 3, 4, and 5 min to assess the effect of ultrasonic pre-treatment on an isolated pure culture-based microbial fuel cell. A 3-min exposure to low-frequency ultrasonic therapy resulted in an increase in maximum power of 4.33 µW/cm 2 with a current density of 51.78 µA/cm 2 in the MFC, which decreases significantly after 4 and 5 min. Thus, the overall power density achieved was 1.89 times greater than in MFCs with untreated strain. These findings support the use of low-frequency ultrasonic stimulation to improve the performance of microbial fuel cell devices and are restricted to the pure, single-cell strain AD1-ELB, with the potential for variation if some other isolated strain is utilized, hence requiring further study to determine its relative variations.

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Section: Electrochemical Calculationsmentioning

confidence: 99%

Ultrasonic pre-treatment of Bacillus velezensis for improved electrogenic response in a single chambered microbial fuel cell

et al. 2021

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“…Besides adsorption, mechanisms like oxidation, precipitation and anaerobic digestion cumulatively help in overall COD reduction and pollutant removal [11–14] . Moreover, availability of the high surface area due to the presence of biochar may be a key factor to facilitate overall pollutant degradation and removal by way of enhanced biofilm formation besides improved adsorption of pollutants [7] …”

Section: Resultsmentioning

confidence: 99%

“…Extensive studies in past have been done for evaluating the efficiency of different wastewater treatment technologies which depend upon chemical, physical adsorption and biological degradation methods for the decolorization of azo dyes [4–6] . Coagulation‐flocculation methods have also been widely used for removal of dyes [7,8] . These methods, however, require enormous quantities of chemicals and generate sludge as a by‐product, thus requiring additional collection and disposal.…”

Section: Introductionmentioning

confidence: 99%

Integrated Constructed Wetland‐Microbial Fuel Cell using Biochar as Wetland Matrix: Influence on Power Generation and Textile Wastewater Treatment

Sonu¹,

Sogani

Syed

2021

ChemistrySelect

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The present study aims at integrating Constructed Wetland using biochar as matrix with Microbial Fuel Cell (CW‐MFC) and evaluating its effect on textile wastewater (TW) treatment in the form of removal of COD, Color and TDS along with Bioelectricity generation. Two vertical down flow systems of CW‐MFC were investigated for TW treatment and system reusability (with and without corn cob biochar) in batch mode with retention time of 10 days for 10 cycles. The performance of CW‐MFC with the corn cob biochar (CW‐MFC−A) was better than the CW‐MFC without corn cob biochar (CW‐MFC−B) in terms of parameters of TW treatment, bioelectricity generation and matrix reusability. The maximum power density, COD removal efficiency, decolorization efficiency and TDS reduction as obtained with CW‐MFC−A (102.08 mW/m2; 83 %; 90 %; 84 % respectively) were higher in comparison to the values obtained in CW‐MFC−B (78.24 mW/m2; 66 %; 65 %; 67 % respectively). Furthermore, the germination assessment studies using the treated effluent from CW‐MFC−A resulted in 100 % germination of Vigna radiata seeds indicating the usefulness of corn cob biochar as wetland matrix for treatment of wastewaters.

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“…In addition, the PMFC has the potential to expand into many wetlands and plains that are not suitable for agricultural production, and therefore, these can be converted into a power plant. Urban areas suffer from green coverage due to the rapid rate of development and expansion, which ends in poor air quality [10][11][12][13][14][15][16][17]. Thus, the diversity of vegetation that grows in urban areas, especially indoor and rooftop areas, can be a source of stagnant energy from PMFCs, generating living electricity and conserving our environment [18][19][20].…”

Section: Introductionmentioning

confidence: 99%

Performance evaluation of Tagetes erecta plant microbial fuel cell using the composite ceramic anode of rice‐husk, mild‐steel dust, and soil

et al. 2022

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This study deals with the fabrication of a low‐cost ceramic anode made by blending the rice husk and mild steel dust with soil (RMS anode) for its application in plant microbial fuel cells (PMFCs). The high cost of electrode material has been a major concern in practical applications of the PMFC technology, but the present composition of waste materials such as rice husk, mild steel dust along with soil has served as an alternative low‐cost electrode material. Tagetes erecta plant has been used to produce clean and continuous electrical energy in the PMFC. The blending of rice husk has improved the porosity of the ceramic anode. The maximum power density recorded in PMFC with 50% rice husk anode was 1.4 mW/m2 as against 0.26 mW/m2 with the anode without rice husk. High biomass growth in terms of better plant height and higher chlorophyll content was also detected in the PMFC system within 60 working days.

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Effect of Corncob Derived Biochar on Microbial Electroremediation of Dye Wastewater and Bioenergy Generation

Cited by 20 publications

References 32 publications

Ultrasonic pre-treatment of Bacillus velezensis for improved electrogenic response in a single chambered microbial fuel cell

Ultrasonic pre-treatment of Bacillus velezensis for improved electrogenic response in a single chambered microbial fuel cell

Integrated Constructed Wetland‐Microbial Fuel Cell using Biochar as Wetland Matrix: Influence on Power Generation and Textile Wastewater Treatment

Performance evaluation of Tagetes erecta plant microbial fuel cell using the composite ceramic anode of rice‐husk, mild‐steel dust, and soil

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