Yeast and carbon nanotube based biocatalyst developed by synergetic effects of covalent bonding and hydrophobic interaction for performance enhancement of membraneless microbial fuel cell
作者: Marcelinus Christwardana , Yongchai Kwon
DOI: 10.1016/J.BIORTECH.2016.11.051
关键词: Hydrophobic effect 、 Catalysis 、 Microbial fuel cell 、 Saccharomyces cerevisiae 、 Carbon nanotube 、 Energy source 、 Chemical engineering 、 Biochemistry 、 Yeast 、 Chemistry 、 Covalent bond 、 Renewable Energy, Sustainability and the Environment 、 Environmental engineering 、 Waste Management and Disposal 、 Bioengineering 、 General Medicine
摘要: Abstract Membraneless microbial fuel cell (MFC) employing new catalyst formed as yeast cultivated from Saccharomyces cerevisiae and carbon nanotube (yeast/CNT) is suggested. To analyze its catalytic activity performance stability of MFC, several characterizations are performed. According to the characterizations, shows excellent activities by facile transfer electrons via reactions NAD, FAD, cytochrome c a 3, while it induces high maximum power density (MPD) (344 mW·m −2 ). It implies that adoption increases in MFC performance. Furthermore, MPD maintained 86% initial value even after eight days, showing stability.
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Khadijeh Sherafatmand, Zeinab Salehi, Shohreh Fatemi, Kinetic study of acetaldehyde conversion to ethanol by free and CNT-immobilized baker's yeast in a gas-phase packed bed reactor Journal of Industrial and Engineering Chemistry. ,vol. 30, pp. 160- 166 ,(2015) , 10.1016/J.JIEC.2015.05.017
Maksim Zakhartsev, Xuelian Yang, Matthias Reuss, Hans Otto Pörtner, None, Metabolic efficiency in yeast Saccharomyces cerevisiae in relation to temperature dependent growth and biomass yield Journal of Thermal Biology. ,vol. 52, pp. 117- 129 ,(2015) , 10.1016/J.JTHERBIO.2015.05.008
Harvey F. Lodish, Molecular Cell Biology ,(1986)
Alyssa L. Walker, Charles W. Walker, Biological fuel cell and an application as a reserve power source Journal of Power Sources. ,vol. 160, pp. 123- 129 ,(2006) , 10.1016/J.JPOWSOUR.2006.01.077
Bruce E. Logan, Bert Hamelers, René Rozendal, Uwe Schröder, Jürg Keller, Stefano Freguia, Peter Aelterman, Willy Verstraete, Korneel Rabaey, Microbial Fuel Cells: Methodology and Technology† Environmental Science & Technology. ,vol. 40, pp. 5181- 5192 ,(2006) , 10.1021/ES0605016
W. H. Macintire, J. W. Hammond, Removal of Fluorides from Natural Waters by Calcium Phosphates Industrial & Engineering Chemistry. ,vol. 30, pp. 160- 162 ,(1938) , 10.1021/IE50338A010
Derek R Lovley, The Microbe Electric: Conversion of Organic Matter to Electricity Current Opinion in Biotechnology. ,vol. 19, pp. 564- 571 ,(2008) , 10.1016/J.COPBIO.2008.10.005
Enas Taha Sayed, Takuya Tsujiguchi, Nobuyoshi Nakagawa, Catalytic activity of baker's yeast in a mediatorless microbial fuel cell Bioelectrochemistry. ,vol. 86, pp. 97- 101 ,(2012) , 10.1016/J.BIOELECHEM.2012.02.001
Nicholas D Haslett, Frankie J Rawson, Frèdèric Barriëre, Gotthard Kunze, Neil Pasco, Ravi Gooneratne, Keith HR Baronian, None, Characterisation of yeast microbial fuel cell with the yeast Arxula adeninivorans as the biocatalyst. Biosensors and Bioelectronics. ,vol. 26, pp. 3742- 3747 ,(2011) , 10.1016/J.BIOS.2011.02.011
Mostafa Rahimnejad, Ghasem Darzi Najafpour, Ali Asghar Ghoreyshi, Farid Talebnia, Giuliano C Premier, Gholamreza Bakeri, Jung Rae Kim, Sang-Eun Oh, None, Thionine increases electricity generation from microbial fuel cell using Saccharomyces cerevisiae and exoelectrogenic mixed culture Journal of Microbiology. ,vol. 50, pp. 575- 580 ,(2012) , 10.1007/S12275-012-2135-0