T
Thomas A. Moore
Researcher at Arizona State University
Publications - 449
Citations - 32656
Thomas A. Moore is an academic researcher from Arizona State University. The author has contributed to research in topics: Electron transfer & Porphyrin. The author has an hindex of 87, co-authored 437 publications receiving 30666 citations. Previous affiliations of Thomas A. Moore include Fundamental Research on Matter Institute for Atomic and Molecular Physics & North Carolina State University.
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Mimicking photosynthetic solar energy transduction
TL;DR: The overall energy transduction process in the liposomal system mimics the solar energy conversion system of a photosynthetic bacterium and illustrates the advantages of designing functional nanoscale devices based on biological paradigms.
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Solar Fuels via Artificial Photosynthesis
TL;DR: Although attempts at artificial photosynthesis fall short of the efficiencies necessary for practical application, they illustrate that solar fuel production inspired by natural photosynthesis is achievable in the laboratory.
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Comparing photosynthetic and photovoltaic efficiencies and recognizing the potential for improvement.
Robert E. Blankenship,David M. Tiede,James Barber,James Barber,Gary W. Brudvig,Graham R. Fleming,Graham R. Fleming,Maria L. Ghirardi,Marilyn R. Gunner,Wolfgang Junge,David Kramer,Anastasios Melis,Thomas A. Moore,Christopher C. Moser,Daniel G. Nocera,Arthur J. Nozik,Arthur J. Nozik,Donald R. Ort,William W. Parson,Roger C. Prince,Richard T. Sayre +20 more
TL;DR: Natural photosynthesis is compared with present technologies for photovoltaic-driven electrolysis of water to produce hydrogen and opportunities in which the frontiers of synthetic biology might be used to enhance natural photosynthesis for improved solar energy conversion efficiency are considered.
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Reproducible Measurement of Single-Molecule Conductivity
Xiaodong Cui,A. Primak,A. Primak,Xristo Zarate,John K. Tomfohr,Otto F. Sankey,Ana L. Moore,Thomas A. Moore,Devens Gust,G. Harris,Stuart Lindsay +10 more
TL;DR: It is shown that the measurement of intrinsic molecular properties requires chemically bonded contacts, and nonbonded contacts to octanethiol monolayers were at least four orders of magnitude more resistive, less reproducible, and had a different voltage dependence.