2017
DOI: 10.1021/jacs.7b05591
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Lattice-Hydride Mechanism in Electrocatalytic CO2 Reduction by Structurally Precise Copper-Hydride Nanoclusters

Abstract: Copper electrocatalysts can reduce CO to hydrocarbons at high overpotentials. However, a mechanistic understanding of CO reduction on nanostructured Cu catalysts has been lacking. Herein we show that the structurally precise ligand-protected Cu-hydride nanoclusters, such as CuHL (L is a dithiophosphate ligand), offer unique selectivity for electrocatalytic CO reduction at low overpotentials. Our density functional theory (DFT) calculations predict that the presence of the negatively charged hydrides in the cop… Show more

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Cited by 307 publications
(253 citation statements)
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“…The bond lengths and Bader charges for these two cases (b and c) and the unsubstituted surface are provided in Table 1 . It is also interesting to observe that the resulting hydride is more hydridic in both case b and case c. The extra negative charge on the hydride facilitates the charge transfer from the catalyst surface to CO 2 , causing the C—O bond to lengthen and break 42, 45, 48…”
Section: Resultsmentioning
confidence: 99%
“…The bond lengths and Bader charges for these two cases (b and c) and the unsubstituted surface are provided in Table 1 . It is also interesting to observe that the resulting hydride is more hydridic in both case b and case c. The extra negative charge on the hydride facilitates the charge transfer from the catalyst surface to CO 2 , causing the C—O bond to lengthen and break 42, 45, 48…”
Section: Resultsmentioning
confidence: 99%
“…[13,[36][37][38] On the Cu-hydride nanocluster, CO 2 reduction follows a different mechanism where CO 2 is activated in the influence of lattice hydride and forms a formate intermediate at an overpotential of 0.32 eV. [39] Herein, our investigation paves a new way of thinking about the hydride assisted pathway for the selective reduction of CO 2 to FA over metal oxide nanoparticles; we have built our understanding around the interaction of CO 2 and dissociation of H 2 on small SnO 2 monomers and dimers, and subsequently investigated a new and selective path for the conversion of CO 2 into formic acid.…”
Section: Introductionmentioning
confidence: 99%
“…[114] A dethiolated site was necessary to Figure 11. [115] It is quite unique that the negatively charged hydrides (H − ) are located at the capping sites and/or the interstitial sites, thus might participate in the reduction leading to new mechanism. b) Distribution of CO binding energetics of randomly sampled sites on Cu NP surface.…”
Section: Nanoparticle and Nanowirementioning
confidence: 99%
“…c) *OCCOH generation process on the proposed surface sites with favored binding. [115] Copyright 2017, The American Chemical Society. Reproduced with permission.…”
Section: Nanoparticle and Nanowirementioning
confidence: 99%