Abstract
The development of cheap, robust and efficient photocatalytic cells for solar powered CO2 reduction would allow the sustainable production of fuel from renewable resources. Progress in this field requires the development of efficient catalytic materials for multielectron reduction reactions and C-C bond formation from CO2. Our photocatalytic cells for biomimetic CO2 fixation are inspired by the Calvin cycle in Nature, where the enzyme RuBisCO facilitates the reaction of CO2 with unsaturated sugar precursors. The cell has three components: (i) a photoanode where solar light is used to extract protons and electrons from water, releasing O2, (ii) an intermediate redox neutral step where Mg2+ Lewis acids couple CO2 with unsaturated polyols to form sugar, and (iii) a cathode where the oxidized polyol is catalytically reduced. We report the synthesis and spectroscopic characterization of two biomimetic Mg complexes as well as the computational analysis based on quantum chemistry modeling of reaction intermediates.
Original language | English (US) |
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Journal | ACS National Meeting Book of Abstracts |
State | Published - 2011 |
All Science Journal Classification (ASJC) codes
- General Chemistry
- General Chemical Engineering