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Autori principali: Li, Wei, Wang, Sixu, Peng, Pai, Han, Haojie, Wang, Xinbo, Ma, Jing, Luo, Jianlin, Liu, Jun-Ming, Li, Jing-Feng, Nan, Ce-Wen, Li, Qian
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2504.17228
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author Li, Wei
Wang, Sixu
Peng, Pai
Han, Haojie
Wang, Xinbo
Ma, Jing
Luo, Jianlin
Liu, Jun-Ming
Li, Jing-Feng
Nan, Ce-Wen
Li, Qian
author_facet Li, Wei
Wang, Sixu
Peng, Pai
Han, Haojie
Wang, Xinbo
Ma, Jing
Luo, Jianlin
Liu, Jun-Ming
Li, Jing-Feng
Nan, Ce-Wen
Li, Qian
contents Ultrafast coherent control of electric dipoles using strong terahertz (THz) pulses provides a means to discover hidden phases of materials and potentially leads to applications in high-speed electro-optic devices. The effectiveness of this means, albeit demonstrated in architype (incipient) ferroelectric systems such as SrTiO3, hinges on a spectral overlapping between their soft phonon modes within the excitation bandwidth of THz pulses. Generally this can only induce an appreciable coupling close to the phase transition temperatures, where the lattice phonons substantially soften. Because of their emergent subterahertz collective dynamics, a fundamentally distinct and effective THz coupling mechanism can be envisaged in topological polar structures recently discovered in PbTiO3/SrTiO3 superlattices. Here, we show that polar skyrmions can be coherently driven into a hidden phase with transient macroscopic polarization, as probed based on THz field-induced second harmonic generation and optical Kerr effects. Such an ultrafast THz-driven phase transition is found to sustain across a broad temperature range of 4-470 K, in accordance with the equilibrium stability field of the skyrmions. Supplemented by dynamical phase-field simulations, we identify the spatial symmetries and relaxation behaviors of the excited collective modes, thereby revealing their correlation with the emergence of the polar phases. Our results unveil the exotic dynamical properties of topological polar structures, which could be technologically exploited given their remarkable flexibility in structure design and tunability under external fields.
format Preprint
id arxiv_https___arxiv_org_abs_2504_17228
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Broad-temperature-range ultrafast terahertz excitation of collective dynamics in polar skyrmions
Li, Wei
Wang, Sixu
Peng, Pai
Han, Haojie
Wang, Xinbo
Ma, Jing
Luo, Jianlin
Liu, Jun-Ming
Li, Jing-Feng
Nan, Ce-Wen
Li, Qian
Materials Science
Ultrafast coherent control of electric dipoles using strong terahertz (THz) pulses provides a means to discover hidden phases of materials and potentially leads to applications in high-speed electro-optic devices. The effectiveness of this means, albeit demonstrated in architype (incipient) ferroelectric systems such as SrTiO3, hinges on a spectral overlapping between their soft phonon modes within the excitation bandwidth of THz pulses. Generally this can only induce an appreciable coupling close to the phase transition temperatures, where the lattice phonons substantially soften. Because of their emergent subterahertz collective dynamics, a fundamentally distinct and effective THz coupling mechanism can be envisaged in topological polar structures recently discovered in PbTiO3/SrTiO3 superlattices. Here, we show that polar skyrmions can be coherently driven into a hidden phase with transient macroscopic polarization, as probed based on THz field-induced second harmonic generation and optical Kerr effects. Such an ultrafast THz-driven phase transition is found to sustain across a broad temperature range of 4-470 K, in accordance with the equilibrium stability field of the skyrmions. Supplemented by dynamical phase-field simulations, we identify the spatial symmetries and relaxation behaviors of the excited collective modes, thereby revealing their correlation with the emergence of the polar phases. Our results unveil the exotic dynamical properties of topological polar structures, which could be technologically exploited given their remarkable flexibility in structure design and tunability under external fields.
title Broad-temperature-range ultrafast terahertz excitation of collective dynamics in polar skyrmions
topic Materials Science
url https://arxiv.org/abs/2504.17228