@article{ART002159314},
author={임채호 and Song Young Eun and Byong-Hun Jeon and Kim, Jung Rae},
title={Biologically activated graphite fiber electrode for autotrophic acetate production from CO2 in a bioelectrochemical system},
journal={Carbon Letters},
issn={1976-4251},
year={2016},
volume={20},
pages={76-80}
TY - JOUR
AU - 임채호
AU - Song Young Eun
AU - Byong-Hun Jeon
AU - Kim, Jung Rae
TI - Biologically activated graphite fiber electrode for autotrophic acetate production from CO2 in a bioelectrochemical system
JO - Carbon Letters
PY - 2016
VL - 20
IS - null
PB - Korean Carbon Society
SP - 76
EP - 80
SN - 1976-4251
AB - Recently, microbial electrosynthesis (MESs) has been highlighted for the purpose of biological CO2 reduction with simultaneous production of intermediates and value-added chemicals. The bioelectrochemical system (BES), which employs microorganisms and a bacterial community as a biocatalyst, has been developed to convert CO2, a greenhouse gas, into liquid biofuels, such as ethanol and butanol, as well as platform chemicals [1]. Several bacterial species, called cathodophilic microorganisms (e.g., Sporomusa ovata and Clostridium ljungdahlii) were reported to interact with a carbon electrode by accepting electrons supplied externally from a power supply [2-4]. Through this process, oxidized chemical molecules, such as CO2, can be converted to more reduced products, such as acetate and ethanol [4,5]. Since the first report of MESs with S. ovata [3,4], performance has been improved by efforts to optimize the reactor design, regulate the applied potential, and improve the bacterial enrichment method [6-8]. On the other hand, the interaction between microorganism and carbon materials is still unknown, which is the main factor limiting further improvement of the performance of the MES process. For example, insufficient information about microbe-carbon interactions is delaying the advance of the process significantly when the input potential is <−410 mV vs standard hydrogen electrode (SHE), which is the theoretical minimum potential for hydrogen production [9].
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임채호, Song Young Eun, Byong-Hun Jeon and Kim, Jung Rae. (2016). Biologically activated graphite fiber electrode for autotrophic acetate production from CO2 in a bioelectrochemical system. Carbon Letters, 20, 76-80.
임채호, Song Young Eun, Byong-Hun Jeon and Kim, Jung Rae. 2016, "Biologically activated graphite fiber electrode for autotrophic acetate production from CO2 in a bioelectrochemical system", Carbon Letters, vol.20, pp.76-80.
임채호, Song Young Eun, Byong-Hun Jeon, Kim, Jung Rae "Biologically activated graphite fiber electrode for autotrophic acetate production from CO2 in a bioelectrochemical system" Carbon Letters 20 pp.76-80 (2016) : 76.
임채호, Song Young Eun, Byong-Hun Jeon, Kim, Jung Rae. Biologically activated graphite fiber electrode for autotrophic acetate production from CO2 in a bioelectrochemical system. 2016; 20 76-80.
임채호, Song Young Eun, Byong-Hun Jeon and Kim, Jung Rae. "Biologically activated graphite fiber electrode for autotrophic acetate production from CO2 in a bioelectrochemical system" Carbon Letters 20(2016) : 76-80.
임채호; Song Young Eun; Byong-Hun Jeon; Kim, Jung Rae. Biologically activated graphite fiber electrode for autotrophic acetate production from CO2 in a bioelectrochemical system. Carbon Letters, 20, 76-80.
임채호; Song Young Eun; Byong-Hun Jeon; Kim, Jung Rae. Biologically activated graphite fiber electrode for autotrophic acetate production from CO2 in a bioelectrochemical system. Carbon Letters. 2016; 20 76-80.
임채호, Song Young Eun, Byong-Hun Jeon, Kim, Jung Rae. Biologically activated graphite fiber electrode for autotrophic acetate production from CO2 in a bioelectrochemical system. 2016; 20 76-80.
임채호, Song Young Eun, Byong-Hun Jeon and Kim, Jung Rae. "Biologically activated graphite fiber electrode for autotrophic acetate production from CO2 in a bioelectrochemical system" Carbon Letters 20(2016) : 76-80.