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Hauptverfasser: Liu, Wen-Hao, Guo, Feng-Wu, Wang, Lin-Wang, Luo, Jun-Wei
Format: Preprint
Veröffentlicht: 2025
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Online-Zugang:https://arxiv.org/abs/2505.03143
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author Liu, Wen-Hao
Guo, Feng-Wu
Wang, Lin-Wang
Luo, Jun-Wei
author_facet Liu, Wen-Hao
Guo, Feng-Wu
Wang, Lin-Wang
Luo, Jun-Wei
contents Recent experiments suggest that atomic disordering dynamics are more universal than conventional coherent processes in photoinduced phase transitions (PIPTs), yet its mechanism remains unclear. Using real-time time-dependent density functional theory (rt-TDDFT), we find that, at lower photoexcitation, higher lattice temperature accelerates atomic disordering, which thereby lowers the threshold for phase transition, by thermally exciting more phonons to randomize the lattice vibrations in VO$_2$. Above this threshold, however, we observe that the transition timescale and atomic disordering become temperature-independent since thermally excited lattice vibrations induce a similar evolution of photoexcited holes. Additionally, we show that photoexcitation initially elongates the V-V dimers followed by a rotation with tangential displacements (along the z-axis) mediated by O atoms, resulting in strongly correlated motion along the z-axis. Consequently, atomic disordering is more dominant along the x direction, attributed to the relatively unrestricted motion of V-V dimers along this direction. The motion of V atoms along the z-axis is more constrained, leading to less disorder along the z-axis, which results in a "correlated disorder" phenomenon. This anisotropic disordering in VO$_2$ offers new insights into PIPTs mechanisms, guiding future studies on photoinduced disordered transitions.
format Preprint
id arxiv_https___arxiv_org_abs_2505_03143
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Ultrafast dynamics of atomic correlated disordering in photoinduced VO$_2$
Liu, Wen-Hao
Guo, Feng-Wu
Wang, Lin-Wang
Luo, Jun-Wei
Materials Science
Mesoscale and Nanoscale Physics
Computational Physics
Recent experiments suggest that atomic disordering dynamics are more universal than conventional coherent processes in photoinduced phase transitions (PIPTs), yet its mechanism remains unclear. Using real-time time-dependent density functional theory (rt-TDDFT), we find that, at lower photoexcitation, higher lattice temperature accelerates atomic disordering, which thereby lowers the threshold for phase transition, by thermally exciting more phonons to randomize the lattice vibrations in VO$_2$. Above this threshold, however, we observe that the transition timescale and atomic disordering become temperature-independent since thermally excited lattice vibrations induce a similar evolution of photoexcited holes. Additionally, we show that photoexcitation initially elongates the V-V dimers followed by a rotation with tangential displacements (along the z-axis) mediated by O atoms, resulting in strongly correlated motion along the z-axis. Consequently, atomic disordering is more dominant along the x direction, attributed to the relatively unrestricted motion of V-V dimers along this direction. The motion of V atoms along the z-axis is more constrained, leading to less disorder along the z-axis, which results in a "correlated disorder" phenomenon. This anisotropic disordering in VO$_2$ offers new insights into PIPTs mechanisms, guiding future studies on photoinduced disordered transitions.
title Ultrafast dynamics of atomic correlated disordering in photoinduced VO$_2$
topic Materials Science
Mesoscale and Nanoscale Physics
Computational Physics
url https://arxiv.org/abs/2505.03143