BioHydrogenOskar R. Zaborsky Springer Science & Business Media, 30. 8. 2007 - Počet stran: 552 The world needs clean and renewable energy and hydrogen represents an almost ideal resource. Hydrogen is the simplest and most abundant molecule in the universe, yet one that is a challenge to produce from renewable resources. Biohydrogen, or hydrogen produced from renewable resources such as water or organic wastes by biological means, is a goal worthy of increased global attention and resources. The purpose of BioHydrogen '97 was to bring together leaders in the biological p- duction of hydrogen from the United States, Japan, Europe, and elsewhere to exchange scientific and technical information and catalyze further cooperative programs. Parti- pants came from at least different countries representing academia, industry, and g- ernment. Especially important participants were young research scientists and engineers: the next generation of contributors. The conference consisted of plenary presentations, topical sessions, posters, and mini-workshop discussions on key areas of biohydrogen. It was designed to maximize - formation exchange, personal interaction among participants, and formulate new inter- tional initiatives. BioHydrogen '97 was an outgrowth of an international workshop convened by the Research Institute of Innovative Technology for the Earth (RITE) and was held in Tokyo, Japan, November 24-25, 1994. The RITE workshop was highly successful but largely l- ited to traditional biochemical and biological studies and not engineering research topics. |
Obsah
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| 7 | |
The Technology of Biohydrogen | 19 |
Marine Genomes | 31 |
Commencement Challenge | 39 |
Knowledge Research and Biotechnological | 53 |
Molecular Biology of Hydrogenases | 65 |
Improvement of Bacterial LightDependent Hydrogen Production by Altering | 81 |
Algal CO2 Fixation and H₂ Photoproduction | 265 |
Hydrogen Production by Facultative Anaerobe Enterobacter aerogenes | 273 |
Sahara Experiments | 281 |
The Effect of Halobacterium halobium on Photoelectrochemical Hydrogen | 295 |
Photosynthetic Bacterial Hydrogen Production with Fermentation Products | 305 |
Hydrogen Production by Photosynthetic Microorganisms | 319 |
A Key Factor | 329 |
Light Penetration and Wavelength Effect on Photosynthetic Bacteria Culture | 345 |
Application to Hydrogen | 87 |
Electron Transport as a Limiting Factor in Biological Hydrogen Production | 99 |
Reconstitution of an IronOnly Hydrogenase | 105 |
Photosynthetic Bacteria | 115 |
Characterization of a Novel LightHarvesting Mutant of Rhodobacter | 123 |
Hydrogen and 5Aminolevulinic Acid Production by Photosynthetic Bacteria | 133 |
Continuous Hydrogen Production by Rhodobacter sphaeroides O U 001 | 143 |
Photobiological Hydrogen Production by Rhodobacter sphaeroides O U 001 | 151 |
Polyhydroxybutyrate Accumulation and Hydrogen Evolution by Rhodobacter | 157 |
Conversion Efficiencies of Light Energy to Hydrogen by a Novel Rhodovulum | 167 |
Identification of an Uptake Hydrogenase Gene Cluster from Anabaena | 181 |
Tools for Photohydrogen Production? | 189 |
Detection of Marine NitrogenFixing Cyanobacteria Capable of Producing | 197 |
Programmed DNA Rearrangement of a Hydrogenase Gene During Anabaena | 203 |
Effect of Exogenous Substrates on Hydrogen Photoproduction by a Marine | 219 |
Development of Selection and Screening Procedures for Rapid Identification | 227 |
An Overview | 235 |
LightDependent Hydrogen Production of the Green Alga Scenedesmus obliquus | 243 |
Association of Electron Carriers with the Hydrogenase from Scenedesmus | 253 |
A Novel Photoreactor | 353 |
Analysis of Compensation Point of Light Using PlaneType Photosynthetic | 359 |
Hydrogen Production by a FloatingType Photobioreactor | 369 |
Photohydrogen Production Using Photosynthetic Bacterium Rhodobacter | 375 |
Bioreactors for Hydrogen Production | 383 |
A Tubular Integral Gas Exchange Photobioreactor for Biological Hydrogen | 391 |
A Tubular Recycle Photobioreactor for Macroalgal Suspension Cultures | 403 |
Implications | 425 |
Development and Testing in Hawaii | 441 |
An Opportunity | 447 |
Secreted Metabolite Production in Perfusion Plant Cell Cultures | 475 |
Strategies for Bioproduct Optimization in Plant Cell Tissue Cultures | 483 |
The Renilla LuciferaseModified GFP Fusion Protein Is Functional | 493 |
RITE Biological Hydrogen Program | 501 |
Roundtable | 511 |
Program | 519 |
Participant Roster | 529 |
| 543 | |
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acetate algal biomass Anabaena anaerobic analysis bacterium Benemann Biochem biohydrogen biological biomass biophotolysis bioreactor Biotechnol Biotechnology carbon cell concentration chlorophyll cloned CO₂ coli conversion efficiency cultivation cyanobacteria E-mail edited by Zaborsky electron engineering enzyme fermentation ferredoxin Figure glucose green algae growth H₂ H₂ production Hawaii heterocysts hupL hydro Hydrogen Energy hydrogen evolution hydrogen production rate hydrogenase illumination immobilized irradiation Japan Laboratory lactate lactic acid light energy light intensity marine medium membrane metabolic microalgae Microbiol microorganisms Miyake molecular Morocco mutant nitrogen nitrogenase Nostoc PCC O₂ organic acids oxygen Phone photobioreactor photohydrogen photoproduction photosynthetic bacteria photosystem plant cell plasmid Plenum Press protein purple bacteria reaction reactor recycle reinhardtii Rhodobacter sphaeroides sequence sphaeroides RV Spirulina strain substrate subunit sulfolipid Synechocystis Technology tion tube tubular U.S. Department uptake hydrogenase W/m² waste µmol
Odkazy na tuto knihu
Hydrogen as a Fuel: Learning from Nature Richard Cammack,Michel Frey,Robert Robson Omezený náhled - 2001 |
Marine Bioprocess Engineering: Proceedings of an International Symposium ... R. Osinga Náhled není k dispozici. - 1999 |