1. Carbonization and activation of inexpensive semicoke-packed electrodes to enhance power generation of microbial fuel cells
- Author
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Kuichang Zuo, Xia Huang, Peng Liang, Jincheng Wei, and Cao Xiaoxin
- Subjects
Biological Oxygen Demand Analysis ,Microbial fuel cell ,Materials science ,Carbonization ,Bioelectric Energy Sources ,General Chemical Engineering ,Coke ,Electrochemistry ,Cathode ,Carbon ,Anode ,law.invention ,General Energy ,Volume (thermodynamics) ,Chemical engineering ,law ,Environmental Chemistry ,General Materials Science ,Electrodes ,Faraday efficiency - Abstract
A simple and low-cost modification method was developed to improve the power generation performance of inexpensive semicoke electrode in microbial fuel cells (MFCs). After carbonization and activation with water vapor at 800-850 °C, the MFC with the activated coke (modified semicoke) anode produced a maximum power density of 74 Wm(-3) , 17 Wm(-3) , and 681 mWm(-2) (normalized to anodic liquid volume, total reactor volume, and projected membrane surface area, respectively), which was 124 % higher than MFCs using a semicoke anode (33 Wm(-3) , 8 Wm(-3) , and 304 mWm(-2) ). When they were used as biocathode materials, activated coke produced a maximum power density of 177 Wm(-3) , 41 Wm(-3) , and 1628 mWm(-2) (normalized to cathodic liquid volume, total reactor volume, and projected membrane surface area, respectively), which was 211 % higher than that achieved by MFCs using a semicoke cathode (57 Wm(-3) , 13 Wm(-3) , and 524 mWm(-2) ). A substantial increase was also noted in the conductivity, C/O mass ratio, and specific area for activated coke, which reduced the ohmic resistance, increased biomass density, and promoted electron transfer between bacteria and electrode surface. The activated coke anode also produced a higher Coulombic efficiency and chemical oxygen demand removal rate than the semicoke anode.
- Published
- 2011