Computational Insights into Ligand Influences on Hydrogen Generation with [Cp*Rh] Hydrides

19 April 2023, Version 1
This content is a preprint and has not undergone peer review at the time of posting.

Abstract

This work reports a computational investigation of the effect of ancillary ligands on the activity of a Rh catalyst for hydrogen evolution based on the [Cp*Rh] motif (Cp* = η5-pentamethylcyclopentadienyl). Specifically, we investigate why a bipyridyl (bpy) ligand leads to H2 generation but diphenylphosphino-based (dpp) ligands do not. We compare the full ligands to simplified models and systematically vary structural features to ascertain their effect on the reaction energy of each catalytic step. The calculations, based on density functional theory, show that the main effect on reactivity is the choice of linker atom, followed by its coordination. In particular, P stabilizes the intermediate Rh-hydride species by donating electron density to the Rh, thus inhibiting the reaction towards H2 generation. Conversely N, a more electron withdrawing center, favors H2 generation at the price of destabilizing the hydride intermediate, which cannot be isolated experimentally and makes determining the mechanism for this reaction more difficult. We also find that steric effects of bulky substituents on the main ligand scaffold can lead to large effects on the reactivity, which may be challenging to fine-tune. On the other hand, structural features like the bite angle of the bidentate ligand have a much smaller impact on reactivity. Therefore, we propose that the choice of linker atom is key for the catalytic activity of this species, which can be further fine-tuned by a proper choice of electron-directing groups on the ligand scaffold.

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Supporting Information: Computational Insights into Ligand Influences on Hydrogen Generation with [Cp*Rh] Hydrides
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Benchmark data on various functionals and basis sets applied to optimizing the geometry of a chlorinated Cp*Rh(dppb) structure (Figure S1); Slope of ∆∆ER for the full, analog, and minimal P(c4) models (Table S1); Average linker NBO charges for the full and analog complexes, overlaid with average linker charge of the P(c4) minimal models (Figure S2); Rhodium and linker Hirshfeld charges (Figure S3); Rhodium and linker CM5 charges (Figure S4); θ and φ angles for each of the full and analog complexes (Table S2); Relative reaction energy of the analog models with respect to bite angle (Figure S5); Cp∗−Rh−L tilt angle (φ) variation with the L−Rh−L bite angle (θ) for each of the full, analog, and P(c4) minimal models (Figure S6); Average linker charge of the minimal models for each reaction (Figure S7); Optimized Model Geometries for the Rh(I), Rh(III)H, and Rh(III)A intermediates in the catalytic cycle (Tables S3-S26).
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