Coproduction of acetic acid and electricity by application of microbial fuel cell technology to vinegar fermentation(BIOCHEMICAL ENGINEERING)
スポンサーリンク
概要
- 論文の詳細を見る
The coproduction of a useful material and electricity via a novel application of microbial fuel cell (MFC) technology to oxidative fermentation was investigated. We focused on vinegar production, i.e., acetic acid fermentation, as an initial and model useful material that can be produced by oxidative fermentation in combination with MFC technology. The coproduction of acetic acid and electricity by applying MFC technology was successfully demonstrated by the simultaneous progress of acetic acid fermentation and electricity generation through a series of repeated batch fermentations. Although the production rate of acetic acid was very small, it increased with the number of repeated batch fermentations that were conducted. We obtained nearly identical (73.1%) or larger (89.9%) acetic acid yields than that typically achieved by aerated fermentation (75.8%). The open-cycle voltages measured before and after fermentation increased with the total fermentation time and reached a maximum value of 0.521 V prior to the third batch fermentation. The maximum current and power densities measured in this study (19.1 μA/cm^2 and 2.47 μW/cm^2, respectively) were obtained after the second batch fermentation.
- 公益社団法人日本生物工学会の論文
著者
-
Ohshima Takayuki
Department Of Biological And Chemical Engineering Gunma University
-
Tanino Takanori
Department Of Chemical And Environmental Engineering Graduate School Of Engineering Gunma University:department Of Chemical Science And Engineering Graduate School Of Engineering Kobe University
-
Tsujiguchi Takuya
Department of Chemical and Environmental Engineering, Graduate School of Engineering, Gunma University
-
Nara Youhei
Department of Chemical and Environmental Engineering, Graduate School of Engineering, Gunma University
関連論文
- BR-P28 Bioethanol production from mixed sugars using sugar uptake ability enhanced yeast strain by overexpression of transporters(Section IV Biorefinery)
- BR-P27 Bioethaol fermentation from mixed sugar by the recombinant yeast with xyloseisomerase pathway(Section IV Biorefinery)
- Inactivation of Bacillus Subtilis Spores by a Combination of Hydrostatic High-Pressure and Pulsed Electric Field Treatments
- Evaluation of the Biodegradability of Polyurethane and Its Derivatives by Using Lipase-Displaying Arming Yeast
- BR-O4 Production of biodiesel fuel in ionic liquids catalyzed by whole-cell biocatalysts(Section IV Biorefinery)
- Ester synthesis reaction with CALB displaying yeast whole cell biocatalyst : Effect of organic solvent and initial water content(ENZYMOLOGY, PROTEIN ENGINEERING, AND ENZYME TECHNOLOGY)
- A Simple and Immediate Method for Simultaneously Evaluating Expression Level and Plasmid Maintenance in Yeast
- Decomposition of organic contaminants by water surface plasma
- INDUCIBLE PRODUCTION OF RECOMBINANT XYLOSE ISOMERASE BY ESCHERICHIA COLI IN FED-BATCH CULTURE
- Cloning and Sequencing of a Gene Encoding Nitrite Reductase from Paracoccus denitrificans and Expression of the Gene in Escherichia coli
- Decomposition of Gaseous Acetaldehyde Using Barrier Discharge Plasma with Fibrous Activated Carbon as an Electrode
- Sugar consumption and ethanol fermentation by transporter-overexpressed xylose-metabolizing Saccharomyces cerevisiae harboring a xyloseisomerase pathway(BIOCHEMICAL ENGINEERING)
- Catalytic activity of yeast extract in biofuel cell(BIOCHEMICAL ENGINEERING)
- Sugar consumption and ethanol fermentation by transporter-overexpressed xylose-metabolizing Saccharomyces cerevisiae harboring a xyloseisomerase pathway
- Coproduction of acetic acid and electricity by application of microbial fuel cell technology to vinegar fermentation(BIOCHEMICAL ENGINEERING)
- Catalytic activity of yeast extract in biofuel cell