Qingfang Chang scite author profile

Platinum group metal dichalcogenides (PtTe 2 ) with controllable thickness have been synthesized and confirmed to be promising electric and spintronic materials. Here, using the firstprinciples calculations, we demonstrate the potential application of PtTe 2 as catalyst substrate. Taking CO oxidation as model reaction, the importance of surface vacancy is clarified. It is found that surface vacancy on PtTe 2 could improve the stability and catalytic activity of the supported Pt atom. The details of CO oxidation processes indicate that surface vacancy could weaken the adsorption of reactants and speed up the formation and decomposition of OOCO intermediate on Pt catalysts. The underlying mechanisms for the improved activity are unveiled through comprehensively analyzing the charge transfer, density of states, and charge density difference. We hope that the current findings were beneficial for the research and development of efficient catalysts by collocating various single atom/cluster catalysts with different platinum group metal dichalcogenides.

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A theoretical study of the improved CO oxidation on WC supported Au monolayer by Cu doping

Chang¹,

Zhang²,

Yang³

2023

Phys. Scr.

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Metal monolayer supported on tungsten carbides have received considerable attention in the field of catalysis, while the adsorption properties of reactants need to be optimized to improve the catalytic activity further. Alloy monolayers on tungsten carbides can deliver different geometric and electronic characters from pure metal layers, owing to the change in local environments. Herein, using the first-principles calculations, the CO oxidation processes on the supported CuAu alloy monolayer on tungsten carbide are systematically investigated and compared with that on pure metal monolayers. It is found that introducing Cu dopant in Au monolayer will elevate the d-band center of the formed alloy monolayer and thus enhancing the adsorption of reactants around the Cu atom, which is caused by the charge redistribution. Especially, the unbalanced interaction strength between Cu-O and Au-O promotes the rotation and migration of oxygen atom to interact with the C atom of CO, which lowers the energy barriers for the formation and dissociation of OOCO intermediate. The oxidation of CO by an atomic O with the largest energy barrier of 0.27 eV along the Langmuir-Hinshelwood pathway is identified as the rate determining step, which is superior or comparable to the reported CO oxidation catalysts. The significance of alloy monolayer on tungsten carbides are further highlighted by comparing the adsorption energy and reaction barrier of rate-limiting step on the pure metal monolayers. This work is insightful for the rational design of highly efficient catalysts based on alloy systems.

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Improved performance of electrochemical reduction of CO2 to HCOOH by Cu incorporation into the supported Au monolayer on tungsten carbide: A DFT study

2023

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Qingfang Chang

First-principles study on the Cu-Au alloy monolayer supported on WC for hydrogen evolution

Fundamental understanding of electrocatalysis over layered double hydroxides from the aspects of crystal and electronic structures

Surface vacancy on PtTe₂ for promoting CO oxidation through efficiently activating O₂

A theoretical study of the improved CO oxidation on WC supported Au monolayer by Cu doping

Improved performance of electrochemical reduction of CO2 to HCOOH by Cu incorporation into the supported Au monolayer on tungsten carbide: A DFT study

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Qingfang Chang

First-principles study on the Cu-Au alloy monolayer supported on WC for hydrogen evolution

Fundamental understanding of electrocatalysis over layered double hydroxides from the aspects of crystal and electronic structures

Surface vacancy on PtTe2 for promoting CO oxidation through efficiently activating O2

A theoretical study of the improved CO oxidation on WC supported Au monolayer by Cu doping

Improved performance of electrochemical reduction of CO2 to HCOOH by Cu incorporation into the supported Au monolayer on tungsten carbide: A DFT study

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Surface vacancy on PtTe₂ for promoting CO oxidation through efficiently activating O₂