Enhancing the Electrochemical Activity of 2D Materials Edges through Oriented Electric Fields.
Hao WangDing-Rui ChenYou-Chen LinPo-Han LinJui-Teng ChangJeyavelan MuthuMario HofmannYa-Ping HsiehPublished in: ACS nano (2024)
The edges of 2D materials have emerged as promising electrochemical catalyst systems, yet their performance still lags behind that of noble metals. Here, we demonstrate the potential of oriented electric fields (OEFs) to enhance the electrochemical activity of 2D materials edges. By atomically engineering the edge of a fluorographene/graphene/MoS 2 heterojunction nanoribbon, strong and localized OEFs were realized as confirmed by simulations and spatially resolved spectroscopy. The observed fringing OEF results in an enhancement of the heterogeneous charge transfer rate between the edge and the electrolyte by 2 orders of magnitude according to impedance spectroscopy. Ab initio calculations indicate a field-induced decrease in the reactant adsorption energy as the origin of this improvement. We apply the OEF-enhanced edge reactivity to hydrogen evolution reactions (HER) and observe a significantly enhanced electrochemical performance, as evidenced by a 30% decrease in Tafel slope and a 3-fold enhanced turnover frequency. Our findings demonstrate the potential of OEFs for tailoring the catalytic properties of 2D material edges toward future complex reactions.
Keyphrases
- ionic liquid
- gold nanoparticles
- room temperature
- molecularly imprinted
- label free
- high resolution
- molecular dynamics
- reduced graphene oxide
- single molecule
- human health
- solid state
- highly efficient
- high glucose
- visible light
- quantum dots
- monte carlo
- molecular dynamics simulations
- density functional theory
- oxidative stress
- climate change
- health risk assessment
- health risk
- heavy metals
- liquid chromatography
- solid phase extraction
- carbon nanotubes
- transition metal
- drinking water