전북대학교
교수프로필
- Major환경생명공학
- Tel063-850-0837
- Fax063-850-0834
- Emailbkim@jbnu.ac.kr
- Lab제2환생대관 404호
- Homepagehttps://sites.google.com/view/eebl
주요 학력
- 2017.02.광주과학기술원 환경공학부 졸업(박사)
- 2012.08.광주과학기술원 환경공학부 졸업(석사)
- 2010.08.인하대학교 환경공학과 졸업(학사)
주요 경력
- 2021.09. ~ 현재전북대학교 생명공학부 조교수
- 2019.09. ~ 2021.08.영국 바스대학교 화학공학과 박사후연구원
- 2018.03. ~ 2019.08.영국 사우스웨일즈대학교 지속가능환경연구센터 박사후연구원
- 2017.03. ~ 2018.02.광주과학기술원 지구환경공학부 박사후연구원
경력 활동
- 대한환경공학회 회원
- International Society for Microbial Electrochemistry and Technology 회원
- 대한환경공학회 회원
- International Society for Microbial Electrochemistry and Technology 회원
주요 수상 경력
- 2016.11.대한환경공학회, 학술연구발표회논문상
- 2014.08.대한환경공학회, 학술연구발표회논문상
- 2013.07.한국미생물생명공학회, 우수포스터발표상
관심 연구 분야
- Microbial electrochemical bioremediation process for contaminated soil and water
- Microbial electrochemical system
- Microbial fuel cell for renewable energy
- Microbial electorsynthesis system for CO2 capture and utilization
수행 연구
- Soil bioremediation based on soil microbial fuel cell
- (Bio)Electrochemical CO2 capture, utilization, extraction (CO2 to Formate)
- Microbial electro-synthesis cell to produce Acetate from CO2
- Development of electrochemical analysis methode for MES (scanning EIS)
- Microbial fuel cell specialized in water/wastewater treatment
- Control for voltage reversal and power overshoot in MFCs
Journal Publications
1. A. Kaur1,*, B. Kim, R. Dinsdale, A. Guwy, E. Yu, and G. Premier (2021) Challenges in Scale up of Electrochemical CO2 Reduction to Formate Integrated with Product Extraction Using Electrodialysis. Journal of Chemical Technology & Biotechnology. 96, 2461-2471
2. E. Casula1, B. Kim1, H. Chesson M. D. Lorenzo*, and M. Mascia* (2021) Modelling the influence of soil properties on performance and bioremediation ability of a pile of soil microbial fuel cells. Electrochimica Acta. 368, 137568
3. B. Kim1,*, I. S. Chang, R. M. Dinsdale and A. J. Guwy (2021) Accurate measurement of internal resistance in microbial fuel cells by improved scanning electrochemical impedance spectroscopy. Electrochimica Acta. 366, 137388
4. B. Kim1, N. Jang, M, Lee, J. K. Jang and I. S. Chang* (2021) Microbial fuel cell driven mineral rich wastewater treatment process for circular economy by creating virtuous cycles. Bioresour. Technol. 320, 124254
5. B. Kim1, S. V. Mohan, D. Fapyane and I. S. Chang* (2020) Controlling Voltage Reversal in Microbial Fuel Cell. Trends in Biotechnology. 38, 6, 667-678
6. B. Kim1 and I. S. Chang* (2018) Elimination of Voltage Reversal in Multiple Membrane Electrode Assembly Installed Microbial Fuel Cells (mMEA-MFCs) Stacking System by Resistor Control. Bioresour. Technol. 262, 338-341
7. S. Choi1, B. Kim, and I. S. Chang* (2018) Tracking of Shewanella oneidensis MR-1 biofilm formation of a microbial electrochemical system via differential pulse voltammetry. Bioresour Technol. 254, 357-361.
8. B. Kim1, S. Choi, J. An and I. S. Chang* (2017) Self-recoverable voltage reversal in stacked microbial fuel cells due to biofilm capacitance. Bioresour. Technol. 245, 1286-1289
9. Y. S. Lee1, J. An, B. Kim, I. S. Chang* (2017) Serially Connectable Sediment Microbial Fuel Cells Using Multi-hole Dipole Graphite Solids and Voltage Reversal Suppression through Manipulation of Ohmic Resistance. Energy Technol. 5, 1946-1952.
10. B. Kim1, J. An and I. S. Chang* (2017) Elimination of Power Overshoot at Bioanode through Assistance Current in Microbial Fuel Cells. ChemSusChem. 10, 612-617
11. J. Kim1, B. Kim, J. An, Y. S. Lee and I. S. Chang* (2016) Development of anode zone using dual-anode system to reduce organic matter crossover in membraneless microbial fuel cells. Bioresour Technol. 213, 140-145.
12. Y. S. Lee1, J. An, B. Kim, H. J. Park, J. Kim and I. S. Chang* (2016) Increased power in sediment microbial fuel cell: facilitated mass transfer with using a water-layer anode in sediment. PLoS ONE. 10(2), e0145430
13. J. Nam1, Y. S. Lee, J. An, B. Kim, H.-S. Lee and I. S. Chang* (2015) Correlation of overvoltages and current densities to estimate optimal electrode size for sediment microbial fuel cells. Energy Technol. 3, 369-374& Technology, 2013; 47: 1128–1136
14. B. Kim1, J. An, D. Fapyane and I. S. Chang* (2015) Bioelectronic platforms for optimal bio-anode of bio-electrochemical systems: from nano- to macro scopes Bioresour. Technol. 195, 2-13 (Review paper)
15. J. An1, J. Nam, B. Kim, H.-S. Lee, B. H. Kim and I. S. Chang* (2015) Performance variation according to anode-embedded orientation in a sediment microbial fuel cell employing a chessboard-like hundred-piece anode. Bioresource Technology. 190, 175-181
16. B. Kim1, B. G. Lee, B. H. Kim and I. S. Chang* (2015) Assistance current effect for prevention of voltage reversal in stacking of microbial fuel cell system. ChemElectroChem, 2 (5), 755-760 &
17. J. An1, B. Kim, I. S. Chang and H.-S. Lee* (2015) Shift of voltage reversal in stacked microbial fuel cell. J. Power Sources. 278, 534-539
18. J. An1, B. Kim, J. K. Jang, H.-S. Lee and I. S. Chang* (2014) New architecture for modulization of membraneless and single-chambered microbial fuel cell using a bipolar plate-electrode assembly (BEA). Biosen. Bioelectron. 59, 28-34
19. B. Kim1, J. An, D. Kim, T. Kim, J. K. Jang, B.-G. Lee and I. S. Chang* (2013) Voltage increase of microbial fuel cells with multiple membrane electrode assemblies by in series connection. Electrochemistry Communications. 28, 131-134
20. J. An1, B. Kim, J. Nam, H. Y. Ng and I. S. Chang* (2013) Comparison in performance of sediment microbial fuel cells according to depth of embedded anode. Bioresource Technology. 127, 138-142
21. D. Kim1, J. An, B. Kim, J. K. Jang, B. H. Kim and I. S. Chang* (2012) Scaling up microbial fuel cells: configuration and potential drop phenomenon at series connection of unit cells in shared anolyte. ChemSusChem. 5, 1086-1091