Electrosorption of organic acids from aqueous bio-oil and conversion into hydrogen via microbial electrolysis cells

Neutralization of the bio-oil pH has been shown to generate a neutralized bio-oil aqueous phase (NBOAP) that includes most of the acidic components and a neutralized bio-oil organic phase (NBOOP) that includes hydrophobic organics, such as phenols. NBOOP can be used for fuel production, while NBOAP...

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Veröffentlicht in:	Renewable energy 2018-09, Vol.125 (C), p.21-31
Hauptverfasser:	Park, Lydia Kyoung-Eun, Satinover, Scott J., Yiacoumi, Sotira, Mayes, Richard T., Borole, Abhijeet P., Tsouris, Costas
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Sprache:	eng
Schlagworte:	09 BIOMASS FUELS Bio-oil Capacitive deionization Electrosorption Microbial electrolysis pH neutralization Pyrolysis oil
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container_end_page	31
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container_title	Renewable energy
container_volume	125
creator	Park, Lydia Kyoung-Eun Satinover, Scott J. Yiacoumi, Sotira Mayes, Richard T. Borole, Abhijeet P. Tsouris, Costas
description	Neutralization of the bio-oil pH has been shown to generate a neutralized bio-oil aqueous phase (NBOAP) that includes most of the acidic components and a neutralized bio-oil organic phase (NBOOP) that includes hydrophobic organics, such as phenols. NBOOP can be used for fuel production, while NBOAP can be fed to microbial electrolysis cells (MECs) for hydrogen production. After pH neutralization, some organic acidic components remain in NBOOP. This work is focused on capturing acidic compounds from NBOOP through water extraction and electrosorption, and demonstrating hydrogen production via MECs. Capacitive deionization (CDI) is proven effective in capturing ions from NBOOP-contacted water and NBOAP via electrosorption. Captured acidic compounds enable the MEC application to effectively produce renewable hydrogen. Chemical oxygen demand (COD) removal of 49.2%, 61.5%, and 60.8% for 2, 4, and 10 g/L-anode/day loading were observed, corresponding to a total COD degradation of 0.19 g/L, 0.79 g/L, and 1.3 g/L, respectively. A maximum hydrogen productivity of 4.3 L-H2/L-anode/day was obtained. Major compounds in the water phase such as fatty acids, sugar derivatives, furanic and phenolic compounds were converted to hydrogen with an efficiency of 80–90%. This approach may lead the entire biomass pyrolysis process to be an overall carbon-neutral process. •pH neutralization of bio-oil produced two liquid phases: aqueous bio-oil and organic bio-oil.•Acidic components were separated from neutralized organic bio-oil using water extraction.•Ions were captured from the extract after water extraction of neutralized organic bio-oil through capacitive deionization.•The hydrogen productivity reached 4.3 L-H2/L-anode/day and the current density peaked at 5.3 A/m2.•80–90% of major compounds in water phases were converted to hydrogen via microbial electrolysis.
doi_str_mv	10.1016/j.renene.2018.02.076
format	Article
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Chemical oxygen demand (COD) removal of 49.2%, 61.5%, and 60.8% for 2, 4, and 10 g/L-anode/day loading were observed, corresponding to a total COD degradation of 0.19 g/L, 0.79 g/L, and 1.3 g/L, respectively. A maximum hydrogen productivity of 4.3 L-H2/L-anode/day was obtained. Major compounds in the water phase such as fatty acids, sugar derivatives, furanic and phenolic compounds were converted to hydrogen with an efficiency of 80–90%. 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(ORNL), Oak Ridge, TN (United States)</creatorcontrib><title>Electrosorption of organic acids from aqueous bio-oil and conversion into hydrogen via microbial electrolysis cells</title><title>Renewable energy</title><description>Neutralization of the bio-oil pH has been shown to generate a neutralized bio-oil aqueous phase (NBOAP) that includes most of the acidic components and a neutralized bio-oil organic phase (NBOOP) that includes hydrophobic organics, such as phenols. NBOOP can be used for fuel production, while NBOAP can be fed to microbial electrolysis cells (MECs) for hydrogen production. After pH neutralization, some organic acidic components remain in NBOOP. This work is focused on capturing acidic compounds from NBOOP through water extraction and electrosorption, and demonstrating hydrogen production via MECs. Capacitive deionization (CDI) is proven effective in capturing ions from NBOOP-contacted water and NBOAP via electrosorption. Captured acidic compounds enable the MEC application to effectively produce renewable hydrogen. Chemical oxygen demand (COD) removal of 49.2%, 61.5%, and 60.8% for 2, 4, and 10 g/L-anode/day loading were observed, corresponding to a total COD degradation of 0.19 g/L, 0.79 g/L, and 1.3 g/L, respectively. A maximum hydrogen productivity of 4.3 L-H2/L-anode/day was obtained. Major compounds in the water phase such as fatty acids, sugar derivatives, furanic and phenolic compounds were converted to hydrogen with an efficiency of 80–90%. 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subjects	09 BIOMASS FUELS Bio-oil Capacitive deionization Electrosorption Microbial electrolysis pH neutralization Pyrolysis oil
title	Electrosorption of organic acids from aqueous bio-oil and conversion into hydrogen via microbial electrolysis cells
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