Netherlands / United States / United Kingdom / / /
Facility
University Place / University of Glasgow / Institute of Molecular Cell / Joseph Black Building / /
IndustryTerm
active site / desired end product / extant chemical process / functional nanoscale systems / redox-active inorganic chemical cells / chemical carbon cycle / energy input / idealized artificial photosynthetic device / Online version / renewable energy sources / chemical sciences / hydrogen peroxide solution / molecular photosynthetic devices / energy supply / external device / artificial photosynthetic systems / aqueous solution / food / energy / artificial photosynthetic device / electricity / energy storage / carbon-neutral energy sources / methanol catalytic site / possible solution / higher energy conversion efficiencies / solar energy utilization / chemical challenges / artificial photosynthetic devices / electrical energy / inorganic chemical cells / renewable energy inputs / natural photosynthetic systems / solar energy / energy transfer catalytic site / homogeneous artificial photosynthetic systems / light-harvesting device / photosynthetic systems / polyoxometalate-containing solution / chemical bonds / capturing the energy / /
Organization
Glasgow Biomedical Research Centre / School of Chemistry / University of Glasgow / Institute of Molecular Cell and Systems Biology / Royal Society / Royal Society/Wolfson Foundation for a Merit / /
Person
Mark D / Nat / Richard J. Cogdell / Mark D. Symes / Leroy Cronin Phil / Phil Trans / Leroy Cronin / / /
Downloaded from rsta.royalsocietypublishing.org on November 29, 2013 Designing artificial photosynthetic devices using hybrid organic −inorganic modules based on polyoxometalates Mark D. Symes, Richard J. Cogdell and