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Polarization Switching of Photocatalytic Solar-to-Hydrogen Conversion in Two-Dimensional Single-Layer Lattices: Insights from First-Principles and Non-adiabatic Molecular Dynamics

Yuliang Liu, Yi-Dong Zhu, Run-Yang Xin, Wenkai Zhao, Xingshuai Lv, Feng Gao, Chuan‐Lu Yang

2025The Journal of Physical Chemistry Letters12 citationsDOI

Abstract

Two-dimensional polar materials with adjustable polarization hold significant potential to improve photocatalytic water-splitting performance. However, due to the distinct mechanism for regulating polarization and photocatalysis, achieving efficient polarization modulation for enhanced photocatalytic efficiency remains challenging. Herein, using first-principles calculations with non-adiabatic molecular dynamics simulations, we identify four single-layer materials of MoXX′N 3 Y (X and X′ = Si and Ge; X ≠ X′; and Y = P and As), whose catalytic activity can be well-tuned by polarization switching. Adjusting electronic asymmetry contributes to effective control of electric polarization, ultimately affecting catalytic reaction paths and carrier dynamics. Consequently, P↑ MoGeSiN 3 Y allows spontaneous redox reactions for overall water splitting, unlike P↓ MoSiGeN 3 Y. Besides, the polarization switching in MoXX′N 3 Y monolayers enhances solar-to-hydrogen conversion efficiency and prolongs carrier lifetimes, thereby achieving a polarization-dependent photocatalytic switch. This study opens an avenue to modify the polarization and significantly improve the catalytic efficiency.

Topics & Concepts

Adiabatic processPolarization (electrochemistry)Chemical physicsMaterials sciencePhotocatalysisHydrogenNanotechnologyPhysicsChemistryPhysical chemistryThermodynamicsQuantum mechanicsBiochemistryCatalysisAdvanced Photocatalysis TechniquesCopper-based nanomaterials and applicationsElectronic and Structural Properties of Oxides
Polarization Switching of Photocatalytic Solar-to-Hydrogen Conversion in Two-Dimensional Single-Layer Lattices: Insights from First-Principles and Non-adiabatic Molecular Dynamics | Litcius