Coverart for item
The Resource Oxygen production and reduction in artificial and natural systems, edited by James Barber, Imperial College London, UK, Alexander V Ruban, Queen Mary University of London, UK, Peter J Nixon, Imperial College London, UK

Oxygen production and reduction in artificial and natural systems, edited by James Barber, Imperial College London, UK, Alexander V Ruban, Queen Mary University of London, UK, Peter J Nixon, Imperial College London, UK

Label
Oxygen production and reduction in artificial and natural systems
Title
Oxygen production and reduction in artificial and natural systems
Statement of responsibility
edited by James Barber, Imperial College London, UK, Alexander V Ruban, Queen Mary University of London, UK, Peter J Nixon, Imperial College London, UK
Contributor
Editor
Subject
Language
eng
Cataloging source
DLC
Dewey number
572/.43
Illustrations
illustrations
Index
index present
LC call number
QH510
LC item number
.O98 2019
Literary form
non fiction
Nature of contents
bibliography
http://library.link/vocab/relatedWorkOrContributorDate
1940-
http://library.link/vocab/relatedWorkOrContributorName
Barber, J.
http://library.link/vocab/subjectName
  • Bioenergetics
  • Energy metabolism
  • Bioenergetics
  • Energy metabolism
Label
Oxygen production and reduction in artificial and natural systems, edited by James Barber, Imperial College London, UK, Alexander V Ruban, Queen Mary University of London, UK, Peter J Nixon, Imperial College London, UK
Instantiates
Publication
Bibliography note
Includes bibliographical references.and index
Carrier category
volume
Carrier category code
  • nc
Carrier MARC source
rdacarrier
Content category
text
Content type code
  • txt
Content type MARC source
rdacontent
Contents
How biology solved its energy problem and implications for the future of humankind -- Theory of rate constants of individual reaction steps in single molecule experiments on F1-ATPase -- Deriving molecular mechanisms of respiratory and photosynthetic enzymes by computational models -- Reflections on redox states in enzymes -- The role of singlet oxygen in photoinhibition of photosystem II -- Modular assembly of atp synthase -- Cytochrome C oxidase: remaining questions about the catalytic mechanism -- Cytochrome C oxidase: oxygen consumption, energy conservation and control -- Mimicking the oxygen-evolving center in photosystem II -- Protein environment that facilitates proton transfer and electron transfer in photosystem II -- Key molecular Ru complexes that have fostered the development and understanding of water oxidation catalysis -- Material design for artificial photosynthesis using photoelectrodes for hydrogen production -- Synthesis, electronic structure, and spectroscopy of multinuclear Mn complexes relevant to the oxygen evolving complex of photosystem II -- Progress towards unraveling the water-oxidation mechanism of photosystem II -- Structure and mechanism of Ni- and Fe-containing carbon monoxide dehydrogenases -- Selective replacement of the damaged D1 reaction center subunit during the repair of the oxygen-evolving photosystem II complex -- Dft investigations on the reaction mechanisms in photosynthetic oxygen evolution -- Local cycle of photosynthesis and quasi-aerobic respiration facilitated by manganese oxides: a hypothesis on the evolution of phototrophy -- A perspective on a paradigm shift in plant photosynthesis: designing a novel type of photosynthesis in sorghum by combining C3 and C4 metabolism
Control code
MSTDDAPRINT1057375949
Dimensions
26 cm
Extent
xx, 416 pages
Isbn
9789813276918
Lccn
2019006784
Media category
unmediated
Media MARC source
rdamedia
Media type code
  • n
Label
Oxygen production and reduction in artificial and natural systems, edited by James Barber, Imperial College London, UK, Alexander V Ruban, Queen Mary University of London, UK, Peter J Nixon, Imperial College London, UK
Publication
Bibliography note
Includes bibliographical references.and index
Carrier category
volume
Carrier category code
  • nc
Carrier MARC source
rdacarrier
Content category
text
Content type code
  • txt
Content type MARC source
rdacontent
Contents
How biology solved its energy problem and implications for the future of humankind -- Theory of rate constants of individual reaction steps in single molecule experiments on F1-ATPase -- Deriving molecular mechanisms of respiratory and photosynthetic enzymes by computational models -- Reflections on redox states in enzymes -- The role of singlet oxygen in photoinhibition of photosystem II -- Modular assembly of atp synthase -- Cytochrome C oxidase: remaining questions about the catalytic mechanism -- Cytochrome C oxidase: oxygen consumption, energy conservation and control -- Mimicking the oxygen-evolving center in photosystem II -- Protein environment that facilitates proton transfer and electron transfer in photosystem II -- Key molecular Ru complexes that have fostered the development and understanding of water oxidation catalysis -- Material design for artificial photosynthesis using photoelectrodes for hydrogen production -- Synthesis, electronic structure, and spectroscopy of multinuclear Mn complexes relevant to the oxygen evolving complex of photosystem II -- Progress towards unraveling the water-oxidation mechanism of photosystem II -- Structure and mechanism of Ni- and Fe-containing carbon monoxide dehydrogenases -- Selective replacement of the damaged D1 reaction center subunit during the repair of the oxygen-evolving photosystem II complex -- Dft investigations on the reaction mechanisms in photosynthetic oxygen evolution -- Local cycle of photosynthesis and quasi-aerobic respiration facilitated by manganese oxides: a hypothesis on the evolution of phototrophy -- A perspective on a paradigm shift in plant photosynthesis: designing a novel type of photosynthesis in sorghum by combining C3 and C4 metabolism
Control code
MSTDDAPRINT1057375949
Dimensions
26 cm
Extent
xx, 416 pages
Isbn
9789813276918
Lccn
2019006784
Media category
unmediated
Media MARC source
rdamedia
Media type code
  • n

Library Locations

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      37.955220 -91.772210
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