AI Article Synopsis
- MoS2 is gaining attention for its catalytic abilities in the hydrogen evolution reaction (HER), especially the metallic 1T phase that shows better conductivity and charge-transfer kinetics compared to the semiconducting 2H phase.
- Researchers introduce a straightforward electrochemical method that adjusts the electron-transfer kinetics and catalytic properties of both exfoliated and bulk MoS2 films through controlled oxidative or reductive treatments.
- The study uses density functional theory to clarify how these electrochemical changes enhance MoS2's performance, suggesting a promising approach for improving electrochemical devices using MoS2.
Article Abstract
MoS2 has become particularly popular for its catalytic properties towards the hydrogen evolution reaction (HER). It has been shown that the metallic 1T phase of MoS2 , obtained by chemical exfoliation after lithium intercalation, possesses enhanced catalytic activity over the semiconducting 2H phase due to the improved conductivity properties which facilitate charge-transfer kinetics. Here we demonstrate a simple electrochemical method to precisely tune the electron-transfer kinetics as well as the catalytic properties of both exfoliated and bulk MoS2 -based films. A controlled reductive or oxidative electrochemical treatment can alter the surface properties of the film with consequently improved or hampered electrochemical and catalytic properties compared to the untreated film. Density functional theory calculations were used to explain the electrochemical activation of MoS2 . The electrochemical tuning of electrocatalytic properties of MoS2 opens the doors to scalable and facile tailoring of MoS2 -based electrochemical devices.
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| http://dx.doi.org/10.1002/chem.201404832 | DOI Listing |
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