The research is based on the single-chamber microbial fuel cell, with the presence of oxygen, we vary the concentration gradient of copper ions, and observe the changes of the electrochemical parameters to explore the practical application of microbial fuel cells as heavy metal sensors. It was found that: the single-chamber microbial fuel cell, the outer barrier of 30min real-time voltage 1000Ω, 100Mmpbs, under 1000mg / LCOD, case, data acquisition card collection, with the change of the concentration gradient, linear development, polarization curves the measured voltage and power density, showing trends X² by multimeter collected anode and cathode potentials, also showed a trend X², in order at the same time, through the environment, COD, PH, and other factors, be optimization process, resulting in more accurate variation for the practical application of microbial fuel cells, providing new ideas.
Published in | Science Discovery (Volume 5, Issue 3) |
DOI | 10.11648/j.sd.20170503.17 |
Page(s) | 199-204 |
Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
Copyright |
Copyright © The Author(s), 2017. Published by Science Publishing Group |
Microbial Fuel Cell, Heavy Metal Sensor, Copperions, Trend
[1] | Y. V. Nancharaiaha, b, ⇑, S. Venkata Mohan c, P. N. L. Lens Metals removal and recovery in bioelectrochemical systems: A review xxx (2015) xxx–xxx. |
[2] | Yan Li , Yining Wu , SampadaPuranik , Yu Lei , Timothy Vadas , Baikun Li Metals as electron acceptors in single-chamber microbial fuel cells 269 (2014) 430-439. |
[3] | Modin O., Wang X., Wu X., et al. Bioelectrochemical recovery of Cu, Pb, Cd, and Zn from dilute solutions.(2012)235–236, 291-297. |
[4] | Carole Abourached, TuncCatal 1, Hong LiuEfficacy of single-chamber microbial fuel cells for removal of cadmium and zinc with simultaneous electricity production 51(2014) 288-233. |
[5] | Choi, C., Hu, N.,.The modeling of gold recovery from tetrachloroauratewastewater using a microbial fuel cell.Bioresour. Technol. 133, (2013)589–598. |
[6] | Zhihao Lu, Dingming Chang, Jingxing Ma, Guangtuan Huang, LankunCai, LehuaZhangBehavior of metal ions in bioelectrochemical systems: A review275 (2015) 243e260. |
[7] | Wang Z., Lim B., Choi C. Removal of Hg2+ as an electron acceptor coupled with power generationusing a microbial fuel cell. Bioresource Technology, 2011, 102(10):6304-6307. |
[8] | Praveena Gangadharan, Indumathi M. Nambi⇑, Jaganathan Senthilnathan Liquid crystal polaroid glass electrode from e-waste for synchronizedremoval/recovery of Cr+6 fromwastewater by microbial fuel cell195 (2015) 96–101. |
[9] | Li H., Feng Y., Zou X., et al. Study on microbial reduction of vanadium matallurgical waste water. Hydrometallurgy, 2009, 99(1–2):13-17. |
[10] | Y. Zhang, L. Yu, D. Wu, L. Huang, P. Zhou, X. Quan, G. Chen, Dependency ofsimultaneous Cr(VI), Cu(II) and Cd(II) reduction on the cathodes of microbialelectrolysis cells self-driven by microbial fuel cells, J. Power Sources 273(2015) 1103–1113 |
[11] | Tandukar M., Huber S. J., Onodera T., et al. Biological Chromium(VI) Reduction in the Cathode of a Microbial Fuel Cell. Environmental Science & Technology, 2009, 43(21):8159-8165. |
[12] | Tao H., Liang M., Li W., et al. Removal of copper from aqueous solution by electrodeposition in cathode chamber of microbial fuel cell. Journal of Hazardous Materials, 2011, 189(1–2):186-192. |
[13] | Jiseon You a, X. Alexis Walter a, John Greenmana,b, Chris Melhuish a, IoannisIeropoulosStability and reliability of anodic biofilms under different feedstock conditions: Towards microbial fuel cell sensors6 (2015) 43–50. |
[14] | SiiriVelling, Toomas TennoDifferent calibration methods of a microbial BOD sensor for analysis of municipal wastewaters141 (2009) 233–238. |
[15] | Nienke Elisabeth Stein a,b,c,1,2, Hubertus M. V. Hamelers a,c,1, Gerrit van Straten b,2, Karel J. KeesmanOn-line detection of toxic components using a microbial fuel cell-based biosensor22 (2012) 1755–1761. |
[16] | SHEN Y J,LEFEBVRE O,TAN Z,et al. Microbial fuel-cell-based toxicity sensor for fast monitoring of acidic toxicity [J].Water SciTechnol, 2012, 65(7):1223-1228. |
APA Style
Wang Ling, Wu Yining, Gao Ya. (2017). Microbial Fuel Cell Wastewater Treatment of Copper-Based Heavy Metal Sensor. Science Discovery, 5(3), 199-204. https://doi.org/10.11648/j.sd.20170503.17
ACS Style
Wang Ling; Wu Yining; Gao Ya. Microbial Fuel Cell Wastewater Treatment of Copper-Based Heavy Metal Sensor. Sci. Discov. 2017, 5(3), 199-204. doi: 10.11648/j.sd.20170503.17
AMA Style
Wang Ling, Wu Yining, Gao Ya. Microbial Fuel Cell Wastewater Treatment of Copper-Based Heavy Metal Sensor. Sci Discov. 2017;5(3):199-204. doi: 10.11648/j.sd.20170503.17
@article{10.11648/j.sd.20170503.17, author = {Wang Ling and Wu Yining and Gao Ya}, title = {Microbial Fuel Cell Wastewater Treatment of Copper-Based Heavy Metal Sensor}, journal = {Science Discovery}, volume = {5}, number = {3}, pages = {199-204}, doi = {10.11648/j.sd.20170503.17}, url = {https://doi.org/10.11648/j.sd.20170503.17}, eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.sd.20170503.17}, abstract = {The research is based on the single-chamber microbial fuel cell, with the presence of oxygen, we vary the concentration gradient of copper ions, and observe the changes of the electrochemical parameters to explore the practical application of microbial fuel cells as heavy metal sensors. It was found that: the single-chamber microbial fuel cell, the outer barrier of 30min real-time voltage 1000Ω, 100Mmpbs, under 1000mg / LCOD, case, data acquisition card collection, with the change of the concentration gradient, linear development, polarization curves the measured voltage and power density, showing trends X² by multimeter collected anode and cathode potentials, also showed a trend X², in order at the same time, through the environment, COD, PH, and other factors, be optimization process, resulting in more accurate variation for the practical application of microbial fuel cells, providing new ideas.}, year = {2017} }
TY - JOUR T1 - Microbial Fuel Cell Wastewater Treatment of Copper-Based Heavy Metal Sensor AU - Wang Ling AU - Wu Yining AU - Gao Ya Y1 - 2017/05/11 PY - 2017 N1 - https://doi.org/10.11648/j.sd.20170503.17 DO - 10.11648/j.sd.20170503.17 T2 - Science Discovery JF - Science Discovery JO - Science Discovery SP - 199 EP - 204 PB - Science Publishing Group SN - 2331-0650 UR - https://doi.org/10.11648/j.sd.20170503.17 AB - The research is based on the single-chamber microbial fuel cell, with the presence of oxygen, we vary the concentration gradient of copper ions, and observe the changes of the electrochemical parameters to explore the practical application of microbial fuel cells as heavy metal sensors. It was found that: the single-chamber microbial fuel cell, the outer barrier of 30min real-time voltage 1000Ω, 100Mmpbs, under 1000mg / LCOD, case, data acquisition card collection, with the change of the concentration gradient, linear development, polarization curves the measured voltage and power density, showing trends X² by multimeter collected anode and cathode potentials, also showed a trend X², in order at the same time, through the environment, COD, PH, and other factors, be optimization process, resulting in more accurate variation for the practical application of microbial fuel cells, providing new ideas. VL - 5 IS - 3 ER -