Open AccessSolar photocatalytic conversion of CO{sub 2} to methanol
Author(s) -
Gail N. Ryba,
John A. Shelnutt,
Michael R. Prairie,
Roger A. Assink
Publication year - 1997
Publication title -
osti oai (u.s. department of energy office of scientific and technical information)
Language(s) - English
Resource type - Reports
DOI - 10.2172/461270
Subject(s) - methanol , photocatalysis , formate , catalysis , electrochemical reduction of carbon dioxide , carbon fibers , formaldehyde , solar energy , materials science , tin , chemistry , photoredox catalysis , photochemistry , carbon monoxide , organic chemistry , ecology , composite number , composite material , biology
This report summarizes the three-year LDRD program directed at developing catalysts based on metalloporphyrins to reduce carbon dioxide. Ultimately it was envisioned that such catalysts could be made part of a solar-driven photoredox cycle by coupling metalloporphyrins with semiconductor systems. Such a system would provide the energy required for CO{sub 2} reduction to methanol, which is an uphill 6-electron reduction. Molecular modeling and design capabilities were used to engineer metalloporphyrin catalysts for converting CO{sub 2} to CO and higher carbon reduction products like formaldehyde, formate, and methanol. Gas-diffusion electrochemical cells were developed to carry out these reactions. A tin-porphyrin/alumina photocatalyst system was partially developed to couple solar energy to this reduction process
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