Felipe Alatriste‐Mondragón scite author profile

Codigestion of organic wastes is a technology that is increasingly being applied for simultaneous treatment of several solid and liquid organic wastes. The main advantages of this technology are improved methane yield because of the supply of additional nutrients from the codigestates and more efficient use of equipment and cost‐sharing by processing multiple waste streams in a single facility. Many municipal wastewater treatment plants (WWTPs) in industrialized countries currently process wastewater sludge in large digesters. Codigestion of organic wastes with municipal wastewater sludge can increase digester gas production and provide savings in the overall energy costs of plant operations. Methane recovery also helps to reduce the emission of greenhouse gases to the atmosphere. The goal of this literature survey was to summarize the research conducted in the last four years on anaerobic codigestion to identify applications of codigestion at WWTPs. Because the solids content in municipal wastewater sludge is low, this survey only focuses on codigestion processes operated at relative low solids content (slurry mode). Semi‐solid or solid codigestion processes were not included.    Municipal wastewater sludge, the organic fraction of municipal solid waste, and cattle manure (CAM) are the main wastes most often used in codigestion processes. Wastes that are codigested with these main wastes are wood wastes, industrial organic wastes, and farm wastes. These are referred to in this survey as codigestates. The literature provides many laboratory studies (batch assays and bench‐scale digesters) that assess the digestibility of codigestates and evaluate the performance and monitoring of codigestion, inhibition of digestion by codigestates, the design of the process (e.g., single‐stage or two‐stage processes), and the operation temperature (e.g., mesophilic or thermophilic). Only a few reports on pilot‐ and full‐scale studies were found. These evaluate general process performance and pretreatment of codigestates, energy production, and treatment costs.

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Fermentative hydrogen production in batch experiments using lactose, cheese whey and glucose: Influence of initial substrate concentration and pH

Davila-Vazquez¹,

Alatriste‐Mondragón²,

León‐Rodríguez³

et al. 2008

International Journal of Hydrogen Energy

201

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Fermentative biohydrogen production: trends and perspectives

Davila-Vazquez

Arriaga

Alatriste‐Mondragón

et al. 2007

Rev Environ Sci Biotechnol

139

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Biologically produced hydrogen (biohydrogen) is a valuable gas that is seen as a future energy carrier, since its utilization via combustion or fuel cells produces pure water. Heterotrophic fermentations for biohydrogen production are driven by a wide variety of microorganisms such as strict anaerobes, facultative anaerobes and aerobes kept under anoxic conditions. Substrates such as simple sugars, starch, cellulose, as well as diverse organic waste materials can be used for biohydrogen production. Various bioreactor types have been used and operated under batch and continuous conditions; substantial increases in hydrogen yields have been achieved through optimum design of the bioreactor and fermentation conditions. This review explores the research work carried out in fermentative hydrogen production using organic compounds as substrates. The review also presents the state of the art in novel molecular strategies to improve the hydrogen production.

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Chemical and enzymatic sequential pretreatment of oat straw for methane production

Gomez-Tovar

Celis

Razo-Flores

et al. 2012

Bioresource Technology

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Methane production from acid hydrolysates of Agave tequilana bagasse: Evaluation of hydrolysis conditions and methane yield

Arreola-Vargas

Ojeda-Castillo

Snell‐Castro

et al. 2015

Bioresource Technology

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Hydrogen production by Escherichia coli ΔhycA ΔlacI using cheese whey as substrate

Rosales-Colunga¹,

Razo-Flores²,

Ordoñez³

et al. 2010

International Journal of Hydrogen Energy

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Different start-up strategies to enhance biohydrogen production from cheese whey in UASB reactors

Carrillo‐Reyes

Celis

Alatriste‐Mondragón

et al. 2012

International Journal of Hydrogen Energy

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