Photocatalytic Water Splitting and Carbon Dioxide Reduction

“…The remaining Re-ligand bonds change a relatively minor amount with the Re-CO and Re-N bonds slightly shortening and the Re-NHC bond slightly increasing in length by ≤0.03 Å. This suggests that the irreversible event occurring upon the first reduction of Re(pyNHC-PhCF 3 )(CO) 3 Br is the loss of Br. The increased lability of this halide is potentially affected by the electron-rich nature of the NHC ring both increasing electron density at the Re center and weakly (relative to a pyridyl) stabilizing the ligand centered anion of the reduced complex.…”

“…The Re-Br bond was found to substantially lengthen upon reduction by 0.08 Å when the neutral catalyst is compared with the singly reduced catalyst. The remaining Re-ligand The computational results also aid in understanding the unique irreversibility of the NHC catalysts toward single-electron reduction when compared with the reversible first reduction of Re(bpy)(CO) 3 Br [10]. The Re-Br bond was found to substantially lengthen upon reduction by 0.08 Å when the neutral catalyst is compared with the singly reduced catalyst.…”

“…Despite more than 30 years of exploration, very few catalysts meet these criteria with a single metal center, and nearly all of them are based on one of five frameworks: Fe-p-TMA, Ir(tpy)(ppy)X, Ir(tpy)(bpy)X, Re(bpy)(CO) 3 X, or Re(pyNHC-R)(CO) 3 X (Figure 1) [7][8][9][10][11][12]. Among these catalysts, the Re(pyNHC-R)(CO) 3 X catalyst is unique in allowing the reduction of CO 2 to occur at the first reduction potential of the neutral catalyst ( Figure 2) [10,13]. Typically, CO 2 reduction photocatalysts first undergo photoexcitation followed by electron transfer from a sacrificial electron donor (SED) to give the anionic catalyst (Figure 2a).…”

“…Here, we reasoned that this group allows better delocalization of the added electron on the singly reduced catalyst across the ligand framework since the lowest energy excitation is thought to be a metal-to-ligand charge transfer (MLCT) followed by addition of an electron [25][26][27]. To analyze the role of the phenyl-CF 3 substituent, the geometry of Re(pyNHC-PhCF 3 )(CO) 3 Br was first optimized with DFT at the M06-L/6-31++G(d,p) level. Analysis of the highest occupied molecular orbital (HOMO) distribution shows the orbital primarily situated on the Re-metal center, the CO ligands, and the Br ligand with no contribution from the pyNHC-PhCF 3 ligand (Figure 3).…”

“…Generic catalytic cycles for catalysts that reduce CO 2 after (a) the second catalyst reduction event, such as benchmark bpy-based Re(bpy)(CO) 3 Br, or (b) the first catalyst reduction event, such as NHC-based Re(pyNHC-PhCF 3 )(CO) 3 Br. The second SED electron transfer likely occurs after CO loss.…”

A Robust Pyridyl-NHC-Ligated Rhenium Photocatalyst for CO2 Reduction in the Presence of Water and Oxygen

“…The remaining Re-ligand bonds change a relatively minor amount with the Re-CO and Re-N bonds slightly shortening and the Re-NHC bond slightly increasing in length by ≤0.03 Å. This suggests that the irreversible event occurring upon the first reduction of Re(pyNHC-PhCF 3 )(CO) 3 Br is the loss of Br. The increased lability of this halide is potentially affected by the electron-rich nature of the NHC ring both increasing electron density at the Re center and weakly (relative to a pyridyl) stabilizing the ligand centered anion of the reduced complex.…”

“…The Re-Br bond was found to substantially lengthen upon reduction by 0.08 Å when the neutral catalyst is compared with the singly reduced catalyst. The remaining Re-ligand The computational results also aid in understanding the unique irreversibility of the NHC catalysts toward single-electron reduction when compared with the reversible first reduction of Re(bpy)(CO) 3 Br [10]. The Re-Br bond was found to substantially lengthen upon reduction by 0.08 Å when the neutral catalyst is compared with the singly reduced catalyst.…”

“…Despite more than 30 years of exploration, very few catalysts meet these criteria with a single metal center, and nearly all of them are based on one of five frameworks: Fe-p-TMA, Ir(tpy)(ppy)X, Ir(tpy)(bpy)X, Re(bpy)(CO) 3 X, or Re(pyNHC-R)(CO) 3 X (Figure 1) [7][8][9][10][11][12]. Among these catalysts, the Re(pyNHC-R)(CO) 3 X catalyst is unique in allowing the reduction of CO 2 to occur at the first reduction potential of the neutral catalyst ( Figure 2) [10,13]. Typically, CO 2 reduction photocatalysts first undergo photoexcitation followed by electron transfer from a sacrificial electron donor (SED) to give the anionic catalyst (Figure 2a).…”

“…Here, we reasoned that this group allows better delocalization of the added electron on the singly reduced catalyst across the ligand framework since the lowest energy excitation is thought to be a metal-to-ligand charge transfer (MLCT) followed by addition of an electron [25][26][27]. To analyze the role of the phenyl-CF 3 substituent, the geometry of Re(pyNHC-PhCF 3 )(CO) 3 Br was first optimized with DFT at the M06-L/6-31++G(d,p) level. Analysis of the highest occupied molecular orbital (HOMO) distribution shows the orbital primarily situated on the Re-metal center, the CO ligands, and the Br ligand with no contribution from the pyNHC-PhCF 3 ligand (Figure 3).…”

“…Generic catalytic cycles for catalysts that reduce CO 2 after (a) the second catalyst reduction event, such as benchmark bpy-based Re(bpy)(CO) 3 Br, or (b) the first catalyst reduction event, such as NHC-based Re(pyNHC-PhCF 3 )(CO) 3 Br. The second SED electron transfer likely occurs after CO loss.…”

A Robust Pyridyl-NHC-Ligated Rhenium Photocatalyst for CO2 Reduction in the Presence of Water and Oxygen

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