Enhancing Biochemical Methane Potential and Enrichment of Specific Electroactive Communities from Nixtamalization Wastewater using Granular Activated Carbon as a Conductive Material

Valero, David; Rico, Carlos; Canto-Canché, Blondy; Domínguez‐Maldonado, Jorge; Tapia-Tussell, Raúl; Cortés‐Velázquez, Alberto; Alzate‐Gaviria, Liliana

doi:10.3390/en11082101

Cited by 27 publications

(6 citation statements)

References 77 publications

(130 reference statements)

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“…It should be noted that the number of electroactive microorganisms is in constant expansion, such as the case of Methanobacteriales or Methanosarcinales (also found in abundance in the biocathode chamber), as recently described [27][28][29]. In addition, the results are in agreement with the observations that some microorganisms, in particular Methanosarcina, were enriched on carbon-based materials such as carbon felt [30] and recent reports point to the ability of this strain to direct exchange electrons with electrified surfaces [28].…”

Section: Composition Of Wastewaters Analysissupporting

confidence: 88%

In Situ Electrochemical Characterization of a Microbial Fuel Cell Biocathode Running on Wastewater

et al. 2021

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The electrochemical features of microbial fuel cells’ biocathodes, running on wastewater, were evaluated by cyclic voltammetry. Ex situ and in situ electrochemical assays were performed and the redox processes associated with the presence of microorganisms and/or biofilms were attained. Different controls using sterile media (abiotic cathode microbial fuel cell) and membranes covering the electrodes were performed to evaluate the source of the electrochemistry response (surface biofilms vs. biotic electrolyte). The bacteria presence, in particular when biofilms are allowed to develop, was related with the enhanced active redox processes associated with an improved catalytic activity, namely for oxygen reduction, when compared with the results attained for an abiotic microbial fuel cell cathode. The microbial main composition was also attained and is in agreement with other reported studies. The current study aims contributing to the establishment of the advantages of using biocathodes rather than abiotic, whose conditions are frequently harder to control and to contribute to a better understanding of the bioelectrochemical processes occurring on the biotic chambers and the electrode surfaces.

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Section: Composition Of Wastewaters Analysissupporting

confidence: 88%

In Situ Electrochemical Characterization of a Microbial Fuel Cell Biocathode Running on Wastewater

et al. 2021

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“…Although the use of different conductive materials (GAC, biochar, nano-magnetite, and minerals) in the production of methane has been evaluated [ 31 , 32 ], this work has focused on GAC, mainly due to its high conductivity of 3,600 µS·cm −1 ; this conductivity is higher than magnetite (160 µS·cm −1 ) and biochar (5 µS·cm −1 ) [ 75 ]. GAC is the ideal conductive material due to its surface area, high conductivity, and economically favorable low cost [ 76 , 77 ].…”

Section: Discussionmentioning

confidence: 99%

Improvement in Methane Production from Pelagic Sargassum Using Combined Pretreatments

Chikani-Cabrera¹,

Fernandes

Tapia-Tussell³

et al. 2022

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The constant golden tides of Sargassum spp., identified to be a mixture of Sargassum natans and Sargassum fluitans, observed recently in the Mexican Caribbean have affected the marine ecosystem and the local economy and have created the need for solutions for their management and use. The Sargassum arrivals have thus been considered as third-generation feedstock for biofuel. Their potential for energetic conversion to biomethane was investigated, with hydrolysis as the limiting step due to its complex composition; therefore, in the present study, different physical, chemical, and enzymatic pretreatments and a combination of them have been evaluated, with the additional use of granular activated carbon, to determine the best yield and methane quality. The combined pretreatments of 2.5% hydrogen peroxide, followed by an enzymatic pretreatment (enzymatic extract from Trametes hirsuta isolated from decomposing wood in the Yucatán Peninsula-Mexico), was the best option, reaching a biodegradability of 95% and maximum methane yield of 387 ± 3.09 L CH4/kg volatile solid. The use of a conductive material, such as granular activated carbon, did not generate significant changes in performance and methane concentration.

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“…. +100 mV if no oxygen is present, with some exceptions [48][49][50][51]) define the following species of dissociation that should be in the solution: HS − , H 2 PO 4 − , NH 4 + ;, and a mixture of CO 2 and HCO 3 − . In such forms, they should be consumed for building anaerobic microbial biomass, with a composition usually expressed as C 5 H 7 O 2 NP 0.06 S 0.1 according to [52][53][54][55].…”

Section: Correction For the Species Of Reaction Productmentioning

confidence: 99%

Sulfur, Phosphorus and Metals in the Stoichiometric Estimation of Biomethane and Biohydrogen Yields

2020

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The estimation of biomethane or biohydrogen yield is used to evaluate energy recovery during the process of the anaerobic treatment of waste and wastewater. Mathematically calculated theoretical values can also be used in biomethane or biohydrogen potential tests as reference points to calculate which fraction of substrate is decomposed, when the substrate degradation stopped and when the sample’s self-digestion begins. This study suggests expanded forms of equations for anaerobic processes leading to either biomethane or biohydrogen. The traditional equations describing the conversion of a substrate with known carbon, hydrogen, oxygen and nitrogen composition were expanded to account for the composition of sulfur (for biohydrogen yields) and phosphorus (both biohydrogen and biomethane yields). As an optional part, one metal cation was also incorporated into the chemical formula of the evaluated wastewater composition in case the compound of biodegradable interest exists as a salt. The equations derived here can be useful for researchers estimating energy recovery based on the elemental analysis of samples, such as algal biomass harvested during harmful algal blooms (HABs). Examples of biomethane and biohydrogen yield estimations from sulfur- and phosphorus-containing compounds are also provided.

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Enhancing Biochemical Methane Potential and Enrichment of Specific Electroactive Communities from Nixtamalization Wastewater using Granular Activated Carbon as a Conductive Material

Cited by 27 publications

References 77 publications

In Situ Electrochemical Characterization of a Microbial Fuel Cell Biocathode Running on Wastewater

In Situ Electrochemical Characterization of a Microbial Fuel Cell Biocathode Running on Wastewater

Improvement in Methane Production from Pelagic Sargassum Using Combined Pretreatments

Sulfur, Phosphorus and Metals in the Stoichiometric Estimation of Biomethane and Biohydrogen Yields

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