期刊
APPLIED BIOCHEMISTRY AND BIOTECHNOLOGY
卷 -, 期 -, 页码 -出版社
SPRINGER
DOI: 10.1007/s12010-022-03997-3
关键词
Microbial fuel cell; Biochar; Anode materials; Biofilm; Power density; Electroactive bacteria
资金
- CNRS through the MITI interdisciplinary programs
The relationship between pyrolysis temperature of woody biomass and physicochemical properties of derived biochar for microbial fuel cell application was investigated in this study. The electrical conductivity of biochar was found to be the key parameter for ensuring efficient anodes in microbial fuel cell application.
In this study, the relationship between pyrolysis temperature of woody biomass and physicochemical properties of derived biochar was investigated for microbial fuel cell (MFC) application. Physical and chemical properties of biochar were characterized for different pyrolysis temperatures. Results showed that biochar obtained at 400 degrees C was not conductor, while biochars prepared at 600 degrees C, 700 degrees C, and 900 degrees C exhibited decreased electrical resistivity of (7 +/- 6) x 10(3 )Omega.m, (1.8 +/- 0.2) Omega.m, and (16 +/- 3) x 10(-3) Omega.m, respectively. Rising pyrolysis temperature from 400 to 700 degrees C exhibited honeycomb-like macroporous structures of biochar with an increase in the specific surface area from 310 to 484 m(2).g(-1). However, the production of biochar at 900 degrees C reduced its specific surface area to 136 m(2).g(-1) and caused the loss of the ordered honeycomb structure. MFCs using anodes based on biochar prepared at 900 degrees C produced maximum power densities ((9.9 +/- 0.6) mW.m(2)) higher than that obtained with biochar pyrolyzed at 700 degrees C ((5.8 +/- 0.1) mW.m(2)) and with conventional carbon felt anodes ((1.9 +/- 0.2) mW.m(2)). SEM images of biochar-based anodes indicated the clogging of macropores in honeycomb structure of biochar prepared at 700 degrees C by growth of electroactive biofilms, which might impede the supply of substrate and the removal of metabolites from the inside of the electrode. These findings highlight that electrical conductivity of biochar is the major parameter for ensuring efficient anodes in microbial fuel cell application.
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