Green plants convert CO(2) to sugar for energy storage via photosynthesis. We report a novel catalyst that uses CO(2) and hydrogen to store energy in formic acid. Using a homogeneous iridium catalyst with a proton-responsive ligand, we show the first reversible and recyclable hydrogen storage system that operates under mild conditions using CO(2), formate and formic acid. This system is energy-efficient and green because it operates near ambient conditions, uses water as a solvent, produces high-pressure CO-free hydrogen, and uses pH to control hydrogen production or consumption. The extraordinary and switchable catalytic activity is attributed to the multifunctional ligand, which acts as a proton-relay and strong π-donor, and is rationalized by theoretical and experimental studies.
A series of 4,4′-dimethyl-2,2′-bipyridyl
ruthenium
complexes with carbonyl ligands were prepared and studied using a
combination of electrochemical and spectroscopic methods with infrared
detection to provide structural information on reaction intermediates
in the photochemical reduction of CO2 to formate in acetonitrile
(CH3CN). An unsaturated 5-coordinate intermediate was characterized,
and the hydride-transfer step to CO2 from a singly reduced
metal-hydride complex was observed with kinetic resolution. While
triethanolamine (TEOA) was expected to act as a proton acceptor to
ensure the sacrificial behavior of 1,3-dimethyl-2-phenyl-2,3-dihydro-1H-benzo[d]imidazole as an electron donor,
time-resolved infrared measurements revealed that about 90% of the
photogenerated one-electron reduced complexes undergo unproductive
back electron transfer. Furthermore, TEOA showed the ability to capture
CO2 from CH3CN solutions to form a zwitterionic
alkylcarbonate adduct and was actively engaged in key catalytic steps
such as metal-hydride formation, hydride transfer to CO2 to form the bound formate intermediate, and dissociation of formate
ion product. Collectively, the data provide an overview of the transient
intermediates of Ru(II) carbonyl complexes and emphasize the importance
of considering the participation of TEOA when investigating and proposing
catalytic pathways.
Proton responsive ligands offer control of catalytic reactions through modulation of pH-dependent properties, second coordination sphere stabilization of transition states, or by providing a local proton source for multiproton, multielectron reactions. Two fac-[Re(I)(α-diimine)(CO)3Cl] complexes with α-diimine = 4,4'- (or 6,6'-) dihydroxy-2,2'-bipyridine (4DHBP and 6DHBP) have been prepared and analyzed as electrocatalysts for the reduction of carbon dioxide. Consecutive electrochemical reduction of these complexes yields species identical to those obtained by chemical deprotonation. An energetically feasible mechanism for reductive deprotonation is proposed in which the bpy anion is doubly protonated followed by loss of H2 and 2H(+). Cyclic voltammetry reveals a two-electron, three-wave system owing to competing EEC and ECE pathways. The chemical step of the ECE pathway might be attributed to the reductive deprotonation but cannot be distinguished from chloride dissociation. The rate obtained by digital simulation is approximately 8 s(-1). Under CO2, these competing reactions generate a two-slope catalytic waveform with onset potential of -1.65 V vs Ag/AgCl. Reduction of CO2 to CO by the [Re(I)(4DHBP-2H(+))(CO)3](-) suggests the interaction of CO2 with the deprotonated species or a third reduction followed by catalysis. Conversely, the reduced form of [Re(6DHBP)(CO)3Cl] converts CO2 to CO with a single turnover.
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