Litcius/Paper detail

Origin of Immediate Damping of Coherent Oscillations in Photoinduced Charge-Density-Wave Transition

Wenhao Liu, Yuxiang Gu, Zhi Wang, Shu‐Shen Li, Lin‐Wang Wang, Jun‐Wei Luo

2023Physical Review Letters17 citationsDOI

Abstract

In stark contrast to the conventional charge density wave (CDW) materials, the one-dimensional CDW on the In/Si(111) surface exhibits immediate damping of the CDW oscillation during the photoinduced phase transition. Here, we successfully reproduce the experimental observation of the photoinduced CDW transition on the In/Si(111) surface by performing real-time time-dependent density functional theory (rt-TDDFT) simulations. We show that photoexcitation promotes valence electrons from the Si substrate to the empty surface bands composed primarily of the covalent p-p bonding states of the long In-In bonds. Such photoexcitation generates interatomic forces to shorten the long In-In bonds and thus drives the structural transition. After the structural transition, these surface bands undergo a switch among different In-In bonds, causing a rotation of the interatomic forces by about π/6 and thus quickly damping the oscillations in feature CDW modes. These findings provide a deeper understanding of photoinduced phase transitions.

Topics & Concepts

PhotoexcitationCharge density waveTime-dependent density functional theoryMaterials scienceOscillation (cell signaling)Molecular physicsPhase transitionCovalent bondCondensed matter physicsDensity functional theoryCharge densityAtomic physicsPhysicsChemistryExcited stateBiochemistryQuantum mechanicsSuperconductivitySurface and Thin Film PhenomenaSemiconductor materials and devicesNanowire Synthesis and Applications