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Molecular Models of Atomically Dispersed Uranium at MoS<sub>2</sub> Surfaces Reveal Cooperative Mechanism of Water Reduction

Kamaless Patra, William W. Brennessel, Ellen M. Matson

2024Journal of the American Chemical Society18 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide Single atoms of uranium supported on molybdenum sulfide surfaces (U@MoS 2 ) have been recently demonstrated to facilitate the hydrogen evolution reaction (HER) through electrocatalysis. Theoretical calculations have predicted uranium hydroxide moieties bound to edge-sulfur atoms of MoS 2 as a proposed transition state involved in the HER process. However, the isolation of relevant intermediates involved in this process remains a challenge, rendering mechanistic hypotheses unverified. The present work describes the isolation and characterization of a uranium-hydroxide intermediate on molybdenum sulfide surfaces using [(Cp* 3 Mo 3 S 4 )UCp*], a molecular model of a reduced uranium center supported at MoS 2 . Mechanistic investigations highlight the metalloligand cooperativity with uranium involved in the water activation pathway. The corresponding uranium-oxo analogue, [(Cp* 3 Mo 3 S 4 )Cp*U(═O)], was also accessed from the hydroxide cluster via hydrogen atom transfer and from [(Cp* 3 Mo 3 S 4 )UCp*] through an alternative direct oxygen atom transfer. These results provide an atomistic perspective on the reactivity of low-valent uranium at molybdenum sulfide surfaces toward water, modeling key intermediates associated with the HER of U@MoS 2 catalysts.

Topics & Concepts

ChemistryUraniumHydroxideMolybdenumCatalysisInorganic chemistrySulfideSulfurOrganic chemistryMetallurgyMaterials scienceElectrocatalysts for Energy ConversionRadioactive element chemistry and processingNuclear Materials and Properties