Calculation of thermodynamic hydricities and the design of hydride donors for CO₂ reduction

We have developed a correlation between experimental and density functional theory-derived results of the hydride-donating power, or “hydricity”, of various ruthenium, rhenium, and organic hydride donors. This approach utilizes the correlation between experimental hydricity values and their correspo...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2012-09, Vol.109 (39), p.15657-15662
Main Authors: Muckerman, James T, Achord, Patrick, Creutz, Carol, Polyansky, Dmitry E, Fujita, Etsuko
Format: Article
Language:English
Subjects:
acetonitrile
Biomimetic Materials - chemistry
calculation
carbon dioxide
Carbon Dioxide - chemistry
CHEMICAL APPROACHES TO ARTIFICIAL PHOTOSYNTHESIS: SOLAR FUELS SPECIAL FEATURE
CO2 reduction
Electrons
Energy
Energy value
Free energy
half life
hydricity
Hydrides
Ligands
Methanol - chemical synthesis
Methanol - chemistry
methanol fuels
Models, Chemical
Molecules
NADP (coenzyme)
NADP - analogs & derivatives
NADP - chemistry
octane
Oxidation-Reduction
Photochemical Processes
Physical Sciences
rhenium
ruthenium
Ruthenium - chemistry
Solvation
Solvents
Thermodynamics
triethylamine
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Summary:We have developed a correlation between experimental and density functional theory-derived results of the hydride-donating power, or “hydricity”, of various ruthenium, rhenium, and organic hydride donors. This approach utilizes the correlation between experimental hydricity values and their corresponding calculated free-energy differences between the hydride donors and their conjugate acceptors in acetonitrile, and leads to an extrapolated value of the absolute free energy of the hydride ion without the necessity to calculate it directly. We then use this correlation to predict, from density functional theory-calculated data, hydricity values of ruthenium and rhenium complexes that incorporate the pbnHH ligand—pbnHH = 1,5-dihydro-2-(2-pyridyl)-benzo[ b ]-1,5-naphthyridine—to model the function of NADPH. These visible light-generated, photocatalytic complexes produced by disproportionation of a protonated-photoreduced dimer of a metal-pbn complex may be valuable for use in reducing CO ₂ to fuels such as methanol. The excited-state lifetime of photoexcited [Ru(bpy) ₂(pbnHH)] ²⁺ is found to be about 70 ns, and this excited state can be reductively quenched by triethylamine or 1,4-diazabicyclo[2.2.2]octane to produce the one-electron-reduced [Ru(bpy) ₂(pbnHH)] ⁺ species with half-life exceeding 50 μs, thus opening the door to new opportunities for hydride-transfer reactions leading to CO ₂ reduction by producing a species with much increased hydricity.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1201026109