Special Microbial ProcessesH.J. REHN (ed) Microbial production of butanol/acetone; Microbial production of 2,3-butanediol; Microbial production of glycerol and other polyols; Microbial production of hydrocarbons; Microbial production of hydrogen; Microbial production of poly-(beta)-hydroxybutyric acid; Microbial and enzymatic production of labeled compounds; Photosynthesis in biotechnology biomimetic models; Processes with plant cell cultures; Processes with animal cell and tissue cultures; Biosensors and "bioelectronics"; Leaching of metals; Accumulation of metals by microorganism and algae; Microbial elimination of nitrogen and phosphorus; Sulfur in biotechnology; Coal in biotechnology; Aerosols and transportation of microorganisms in air; Menbrane biotechnology: two-dimensional protein crystals forultrafiltration purposes; Biotechnology in space; Gliding bacteria in biotechnology; Archaeobacteria; Microorganisms in processing of leather; Microorganisms in processing of flax; Microorganisms in processing of tobaco; Biotechnology in agriculture - an overview. |
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Page 118
... hydrogen in the environment inhibits hydrogen production and conse- quently NADH2 oxidation . Therefore , only in an environment where H2 is continuously removed does NADH2 generated H2 evolu- tion continue . SOUTSCHEK et al . ( 1984 ) ...
... hydrogen in the environment inhibits hydrogen production and conse- quently NADH2 oxidation . Therefore , only in an environment where H2 is continuously removed does NADH2 generated H2 evolu- tion continue . SOUTSCHEK et al . ( 1984 ) ...
Page 123
... hydrogen production for over 100 days ( VINCENZINI et al . 1986 ) . Environmental ( 1986 $ / GJ ) Utilization efficiency reflects. Hydrogen Economy C. Genetically Enhanced Production Perhaps the most significant advances in microbial ...
... hydrogen production for over 100 days ( VINCENZINI et al . 1986 ) . Environmental ( 1986 $ / GJ ) Utilization efficiency reflects. Hydrogen Economy C. Genetically Enhanced Production Perhaps the most significant advances in microbial ...
Page 125
... Hydrogen Methane Table 19. Options for the Transportation of Hydrogen " ). Other Oil refining 3 % 43 % Ammonia 9 % 33 % 12 % Methanol Synthetic fuel Figure 11. Hydrogen feedstock consumption in Canada in 1978. ( Modified from HAMMERLI ...
... Hydrogen Methane Table 19. Options for the Transportation of Hydrogen " ). Other Oil refining 3 % 43 % Ammonia 9 % 33 % 12 % Methanol Synthetic fuel Figure 11. Hydrogen feedstock consumption in Canada in 1978. ( Modified from HAMMERLI ...
Contents
Chapter | 2 |
Industrial Fermentation Process | 14 |
Conclusions | 27 |
Copyright | |
13 other sections not shown
Common terms and phrases
acetate acetobutylicum acetone acid activity algae anaerobic antibody Appl Bacillus bacteria Bacteriol batch Biochem Bioeng Biol biological biomass bioreactor Biosensors Biotechnol Biotechnology butanediol butanol carbon cell culture cell lines cell wall Chem chemical chlorophyll Clostridium acetobutylicum coal compounds concentration cyanobacteria degradation dehydrogenase denitrification duced electron Environ enzyme ethanol extraction fermentation ferrooxidans formation fungi gene gliding bacteria glucose glycerol Glycerol production H₂ hybridoma hydrocarbons hydrogen hydrogenase immobilized increase interferon isolated leaching Lett lignin medium membrane metabolism metal methanogens micro microbial Microbiol microorganisms molecular weight molecules nitrogen organic oxidation oxygen particles pathway phase phosphate photosynthesis phototrophic plant cell Poly-HB protein pyrite pyruvate reaction reactor reduced S-layer sensor sludge solvent species spores strains structure substrate sugar sulfate sulfide sulfur surface synthesis Table Technol temperature thermophilic Thiobacillus tion tissue TORMA ture uptake yeast yield