Copper hydrides are important hydrogenation catalysts, but their poor stability hinders the practical applications. Ligand engineering is an effective strategy to tackle this issue. An amidinate ligand, N,N'-Di(5-trifluoromethyl-2-pyridyl)formamidinate (Tf-dpf) with four N-donors has been applied as a protecting agent in the synthesis of stable copper hydride clusters: CuH(Tf-dpf)(OAc) (Cu) with three interfacial μ-H and [CuH(Tf-dpf)(OAc)]·OAc (Cu) with three interstitial μ-H. A solvent-triggered reversible interconversion between Cu and Cu has been observed thanks to the flexibility of Tf-dpf. Cu shows high activity in the reduction of 4-nitrophenol to 4-aminophenol, while Cu displays very low activity. Deuteration experiments prove that the type of hydride is the key in dictating the catalytic activity, for the interfacial μ-H species in Cu are involved in the catalytic cycle whereas the interstitial μ-H species in Cu are not. This work highlights the role of hydrides with regard to catalytic hydrogenation activity.
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