Continuous acetate production through microbial electrosynthesis from CO2 with microbial mixed culture

BACKGROUND Microbial electrosynthesis represents a promising approach for renewable energy storage in which chemically stable compounds are produced using CO2 as feedstock. This report describes the continuous production of acetate through microbial electrosynthesis from CO2 and assesses how the pro...
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Autor*in:	Batlle‐Vilanova, Pau [verfasserIn] Puig, Sebastià Gonzalez‐Olmos, Rafael Balaguer, Maria Dolors Colprim, Jesús

Format:	Artikel
Sprache:	Englisch

Erschienen:	2016

Rechteinformationen:	Nutzungsrecht: © 2015 Society of Chemical Industry

Schlagwörter:	carbon dioxide valorization electroautotrophs homoacetogenesis biocathode valuable compounds

Übergeordnetes Werk:	Enthalten in: Journal of chemical technology and biotechnology - Chichester, Sussex : Wiley, 1979, 91(2016), 4, Seite 921-927
Übergeordnetes Werk:	volume:91 ; year:2016 ; number:4 ; pages:921-927

Links:	Volltext Link aufrufen Link aufrufen

DOI / URN:	10.1002/jctb.4657

Katalog-ID:	OLC1973846047

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520			\|a BACKGROUND Microbial electrosynthesis represents a promising approach for renewable energy storage in which chemically stable compounds are produced using CO2 as feedstock. This report describes the continuous production of acetate through microbial electrosynthesis from CO2 and assesses how the production rates could be increased. RESULTS A continuous acetate production rate of 0.98mmol C LNCC-1 d-1 was obtained using CO2 as feedstock and with pH control around 5.8. These conditions increased substrate availability and favoured microbial electrosynthesis. Cyclic voltammograms demonstrated the electroautotrophic activity on the biocathode surface, which increased with pH control and caused current demand and acetate production rate to rise exponentially. CONCLUSION pH decrease was shown to be an effective strategy to increase substrate availability and enhance microbial electrosynthesis. By making microbial electrosynthesis a feasible technology, CO2 could become an alternative feedstock for the carboxylate platform. © 2015 Society of Chemical Industry
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title_sort	continuous acetate production through microbial electrosynthesis from co2 with microbial mixed culture
title_auth	Continuous acetate production through microbial electrosynthesis from CO2 with microbial mixed culture
abstract	BACKGROUND Microbial electrosynthesis represents a promising approach for renewable energy storage in which chemically stable compounds are produced using CO2 as feedstock. This report describes the continuous production of acetate through microbial electrosynthesis from CO2 and assesses how the production rates could be increased. RESULTS A continuous acetate production rate of 0.98mmol C LNCC-1 d-1 was obtained using CO2 as feedstock and with pH control around 5.8. These conditions increased substrate availability and favoured microbial electrosynthesis. Cyclic voltammograms demonstrated the electroautotrophic activity on the biocathode surface, which increased with pH control and caused current demand and acetate production rate to rise exponentially. CONCLUSION pH decrease was shown to be an effective strategy to increase substrate availability and enhance microbial electrosynthesis. By making microbial electrosynthesis a feasible technology, CO2 could become an alternative feedstock for the carboxylate platform. © 2015 Society of Chemical Industry
abstractGer	BACKGROUND Microbial electrosynthesis represents a promising approach for renewable energy storage in which chemically stable compounds are produced using CO2 as feedstock. This report describes the continuous production of acetate through microbial electrosynthesis from CO2 and assesses how the production rates could be increased. RESULTS A continuous acetate production rate of 0.98mmol C LNCC-1 d-1 was obtained using CO2 as feedstock and with pH control around 5.8. These conditions increased substrate availability and favoured microbial electrosynthesis. Cyclic voltammograms demonstrated the electroautotrophic activity on the biocathode surface, which increased with pH control and caused current demand and acetate production rate to rise exponentially. CONCLUSION pH decrease was shown to be an effective strategy to increase substrate availability and enhance microbial electrosynthesis. By making microbial electrosynthesis a feasible technology, CO2 could become an alternative feedstock for the carboxylate platform. © 2015 Society of Chemical Industry
abstract_unstemmed	BACKGROUND Microbial electrosynthesis represents a promising approach for renewable energy storage in which chemically stable compounds are produced using CO2 as feedstock. This report describes the continuous production of acetate through microbial electrosynthesis from CO2 and assesses how the production rates could be increased. RESULTS A continuous acetate production rate of 0.98mmol C LNCC-1 d-1 was obtained using CO2 as feedstock and with pH control around 5.8. These conditions increased substrate availability and favoured microbial electrosynthesis. Cyclic voltammograms demonstrated the electroautotrophic activity on the biocathode surface, which increased with pH control and caused current demand and acetate production rate to rise exponentially. CONCLUSION pH decrease was shown to be an effective strategy to increase substrate availability and enhance microbial electrosynthesis. By making microbial electrosynthesis a feasible technology, CO2 could become an alternative feedstock for the carboxylate platform. © 2015 Society of Chemical Industry
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title_short	Continuous acetate production through microbial electrosynthesis from CO2 with microbial mixed culture
url	http://dx.doi.org/10.1002/jctb.4657 http://onlinelibrary.wiley.com/doi/10.1002/jctb.4657/abstract http://search.proquest.com/docview/1770835513
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author2	Puig, Sebastià Gonzalez‐Olmos, Rafael Balaguer, Maria Dolors Colprim, Jesús
author2Str	Puig, Sebastià Gonzalez‐Olmos, Rafael Balaguer, Maria Dolors Colprim, Jesús
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author2_role	oth oth oth oth
doi_str	10.1002/jctb.4657
up_date	2024-07-04T03:15:47.772Z
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