Bioenergy Generation and Phenol Degradation through Microbial Fuel Cells Energized by Domestic Organic Waste

Yaqoob, Asim Ali; Al‐Zaqri, Nabil; Alamzeb, Muhammad; Hussain, Fida; Oh, Sang‐Eun; Umar, Khalid

doi:10.3390/molecules28114349

Cited by 16 publications

(4 citation statements)

References 70 publications

(71 reference statements)

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“…The dependence of the value of the internal resistance of electronic devices is vital because it affects the start-up time, which is why the growth of microorganisms in biofilms occurs at a higher speed at high resistance [59,60]. Yaqoob et al (2023) used rotten rice as a substrate in their MFC, showing an internal resistance of 312.5 Ω using graphite as electrodes. They also mentioned that the increase in internal resistance decreased the mobility of electrons [61].…”

Section: Results and Analysismentioning

confidence: 99%

“…They also mentioned that the increase in internal resistance decreased the mobility of electrons [61]. Likewise, Raychaudhuri et al (2023), in their MFCs, used rice mill wastewater as a substrate, achieving an internal resistance of 372.34 Ω using carbon electrodes, mentioning that high absorbed values of the chemical oxygen demand were due to the high porosity shown of the electrodes [62]. In the literature, it has been found that metallic electrodes or electrodes with metallic inlays improve the performance of an MFC, reducing its internal resistance values due to the inherent properties that these materials have, facilitating the transport of electrons between the anodic and cathodic chambers [63].…”

Section: Results and Analysismentioning

confidence: 99%

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The Potential Use of Pseudomonas stutzeri as a Biocatalyst for the Removal of Heavy Metals and the Generation of Bioelectricity

Segundo,

De La Cruz-Noriega,

Cabanillas-Chirinos

et al. 2024

Fermentation

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Currently, industry in all its forms is vital for the human population because it provides the services and goods necessary to live. However, this process also pollutes soils and rivers. This research provides an environmentally friendly solution for the generation of electrical energy and the bioremediation of heavy metals such as arsenic, iron, and copper present in river waters used to irrigate farmers’ crops. This research used single-chamber microbial fuel cells with activated carbon and zinc electrodes as anodes and cathodes, respectively, and farmers’ irrigation water contaminated with mining waste as substrate. Pseudomonas stutzeri was used as a biocatalyst due to its ability to proliferate at temperatures between 4 and 44 °C—at which the waters that feed irrigated rivers pass on their way to the sea—managing to generate peaks of electric current and voltage of 4.35 mA and 0.91 V on the sixth day, which operated with an electrical conductivity of 222 mS/cm and a pH of 6.74. Likewise, the parameters of nitrogen, total organic carbon, carbon lost on the ignition, dissolved organic carbon, and chemical oxygen demand were reduced by 51.19%, 79.92%, 64.95%, 79.89%, 79.93%, and 86.46%. At the same time, iron, copper, and arsenic values decreased by 84.625, 14.533, and 90.831%, respectively. The internal resistance values shown were 26.355 ± 4.528 Ω with a power density of 422.054 mW/cm2 with a current density of 5.766 A/cm2. This research gives society, governments, and private companies an economical and easily scalable prototype capable of simultaneously generating electrical energy and removing heavy metals.

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Section: Results and Analysismentioning

confidence: 99%

Section: Results and Analysismentioning

confidence: 99%

The Potential Use of Pseudomonas stutzeri as a Biocatalyst for the Removal of Heavy Metals and the Generation of Bioelectricity

Segundo,

De La Cruz-Noriega,

Cabanillas-Chirinos

et al. 2024

Fermentation

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“…The treatment of 1 m 3 of organic waste costs around USD 289, and the expense is more significant in the manufacture of electrodes [51]. Another way to improve the economic viability of microbial fuel cells is by using the sediments generated after waste treatment and the generation of electrical energy as fertilizer or some other type of application [52]. It has also been reported that the use of microbial fuel cells as bioremediations or for the reduction of heavy metals are other applications that can be given to this technology, and it has already been shown that the excess concentration of heavy metals reduces the growth of microbes in cells [53].…”

Section: Results and Analysismentioning

confidence: 99%

Potential Use of Andean Tuber Waste for the Generation of Environmentally Sustainable Bioelectricity

Rojas-Flores,

De La Cruz-Noriega,

Cabanillas-Chirinos

et al. 2024

Molecules

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The growing demand for agricultural products has increased exponentially, causing their waste to increase and become a problem for society. Searching for sustainable solutions for organic waste management is increasingly urgent. This research focuses on considering the waste of an Andean tuber, such as Olluco, as a fuel source for generating electricity and becoming a potential sustainable energy source for companies dedicated to this area. This research used Olluco waste as fuel in single-chamber microbial fuel cells using carbon and zinc electrodes. An electric current and electric potential of 6.4 ± 0.4 mA and 0.99 ± 0.09 V were generated, operating with an electrical conductivity of 142.3 ± 6.1 mS/cm and a pH of 7.1 ± 0.2. It was possible to obtain a 94% decrease in COD and an internal resistance of 24.9 ± 2.8 Ω. The power density found was 373.8 ± 28.8 mW/cm2 and the current density was 4.96 A/cm2. On day 14, the cells were connected in earnest, achieving a power of 2.92 V and generating enough current to light an LED light bulb, thus demonstrating the potential that Olluco waste has to be used as fuel in microbial fuel cells.

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“…[11] Physical, chemical, and biological treatment techniques are used to remove phenol from wastewater. Membrane filtration, flotation, coagulation-flocculation, adsorption, precipitation, and ion exchange [12,13,14,15,16,17] are used as physico-chemical treatment techniques, while aerobic and anaerobic processes, bacterial and fungal biosorption [18,19] are used as biological treatment techniques. However, there are many limitations in these processes, such as high cost and low efficiency, and these processes cannot entirely remove phenolic compounds from wastewater.…”

Section: Introductionmentioning

confidence: 99%

Analysis of Photocatalytic Degradation of Phenol by Zinc Oxide Using Response Surface Methodology

Seloglu,

Orhan,

Selen

et al. 2024

ChemistryOpen

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In this study, the photocatalytic degradation of phenol, which is commonly found in industrial wastewater at high rates, was investigated using a zinc oxide (ZnO) catalyst. It is thought that our findings will contribute to the removal of phenol in industrial wastewater. The experimental study was conducted in a batch‐type air‐fed cylindrical photocatalytic reactor, and a central composite design (CCD) was chosen and analyzed using response surface methodology (RSM). The study aimed to explore the effects of initial phenol concentration, catalyst concentration, airflow rate, and degradation time on the photocatalytic degradation of phenol and the removal efficiency of total organic carbon (TOC). A quadratic regression model was developed to establish the relationship between phenol degradation, TOC removal effectiveness, and the four factors mentioned. The validity of the model was assessed through an analysis of variance (ANOVA). A good agreement was observed between the model results and the experimental data. As a result of the experiments carried out under optimized conditions, the degradation percentage of phenol was found to be 77.15 %, and the degradation percentage of TOC was 59.87 %. Additionally, pseudo‐first‐order kinetics were used in the photocatalytic degradation of phenol.

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Bioenergy Generation and Phenol Degradation through Microbial Fuel Cells Energized by Domestic Organic Waste

Cited by 16 publications

References 70 publications

The Potential Use of Pseudomonas stutzeri as a Biocatalyst for the Removal of Heavy Metals and the Generation of Bioelectricity

The Potential Use of Pseudomonas stutzeri as a Biocatalyst for the Removal of Heavy Metals and the Generation of Bioelectricity

Potential Use of Andean Tuber Waste for the Generation of Environmentally Sustainable Bioelectricity

Analysis of Photocatalytic Degradation of Phenol by Zinc Oxide Using Response Surface Methodology

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