AI Article Synopsis
- Metal hydrides play a key role in various catalytic reactions, with a focus on creating molecular metal hydrides despite challenges with toxic materials and fragile mediators.
- This research introduces a simple method for generating a cost-effective metal hydride surface that facilitates sustainable hydrogen transfer, using zinc as a catalyst for carbon dioxide electroreduction.
- The zinc hydride surface significantly improves the efficiency of turning carbon monoxide (CO) into formate, achieving a Faradaic efficiency of 83%, thus opening up new direct hydrogenation pathways that were previously thought impossible.
Article Abstract
Metal hydrides are crucial intermediates in numerous catalytic reactions. Intensive efforts have been dedicated to constructing molecular metal hydrides, where toxic precursors and delicate mediators are usually involved. Herein, we demonstrate a facile pressure-induced methodology to generate a cost-effective heterogeneous electrocatalytic metal hydride surface for sustainable hydrogen transfer. Taking carbon dioxide (CO) electroreduction as a model system and zinc (Zn), a well-known carbon monoxide (CO)-selective catalyst, as a model catalyst, we showcase a homogeneous-type hydrogen atom transfer process induced by heterogeneous hydride surfaces, enabling direct hydrogenation pathways traditionally considered "prohibited". Specifically, the maximal Faradaic efficiency for formate is enhanced by ~fivefold to 83% under ambient conditions. Experimental and theoretical analyses reveal that unlike the distal hydrogenation route for CO to CO over pristine Zn, the Zn hydride surface enables direct hydrogenation at the carbon site of CO to form formate. This work provides a promising material platform for sustainable synthesis.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11381543 | PMC |
| http://dx.doi.org/10.1038/s41467-024-52228-2 | DOI Listing |
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