Litcius/Paper detail

How water molecules occupying the active site of a single-atom catalyst affect the electrochemical reduction of carbon dioxide

Jia Zhao, Di Liu, Fenfei Wei, Weng Fai Ip, Hui Pan, Sen Lin

2023Nano Research29 citationsDOI

Abstract

In single-atom catalysts (SACs), the single atoms are often exposed as protrusions above the substrate. The solvent molecules in the electrocatalytic environment can interact or even bind to these coordination-unsaturated single atoms and thus influence the reaction process, but this has not been studied in depth. In this work, we systematically investigate the thermodynamics of CO 2 reduction reaction (CO 2 RR) to CO over MoS 2 -supported single metal atom catalysts (TM@MoS 2 , TM = transition metal) under vacuum and explicit solvent environments using density functional theory. In addition, the ab initio molecular dynamics results show that explicit H 2 O molecules can coordinate to the TM site and undergo competitive adsorption with the CO 2 RR intermediates, which significantly affects the energy and conformation of the CO 2 RR pathway. Electronic structure analysis reveals that the occupying H 2 O molecules change the electronic state of single atom and further influence the adsorption strength of different CO 2 RR intermediates. Our work shows that water molecules can not only act as ligands to influence the electronic state of TM, but also affect the energy and conformation of CO 2 RR intermediates, which highlights the important role of occupying H 2 O molecules at the single-atom sites in CO 2 RR and provides useful insights for the design of SACs for efficient CO 2 RR.

Topics & Concepts

MoleculeCatalysisDensity functional theoryChemistryElectrochemistryRedoxAtom (system on chip)AdsorptionReaction coordinateChemical physicsSubstrate (aquarium)Ab initioComputational chemistryInorganic chemistryPhysical chemistryElectrodeOrganic chemistryComputer scienceGeologyEmbedded systemOceanographyCO2 Reduction Techniques and CatalystsElectrocatalysts for Energy ConversionIonic liquids properties and applications