Birefringence modulation via intense coherent phonons engineering with asymmetric VO2/TiO2 heterostructures

IF 10 2区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

Materials Today Physics Pub Date : 2024-08-08 DOI:10.1016/j.mtphys.2024.101533

Ziyue Wang , Fan Zhang , Pierre Vallobra , Yongshan Liu , Xiaoqiang Zhang , Yong Xu , Jiangxiao Li , Yun Sun , Yue Zhang , Bin Hong , Weisheng Zhao

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Abstract

The ultrafast modulation of optical crystal birefringence, involving rapid deformations of crystalline lattices, holds significant scientific and technological importance. High-frequency coherent phonons, through transient perturbation of lattice order, have emerged as a powerful tool for modifying the properties of materials. Here, we systematically investigate coherent phonons in the asymmetric crystal directions [011], [110], and [100] of VO₂/TiO₂ heterostructures. Notably, in the (011)-VO₂/TiO₂ system, a remarkable shear mode coherent phonon signal was excited, exhibiting a marginally higher intensity compared to the longitudinal mode. By changing the probe light polarization, we observed a fascinating reversal in the birefringence sign induced by the giant coherent phonons. Density functional theory (DFT) calculations indicate that TiO₂ possesses excellent photoelastic properties, with strong coherent phonons efficiently modulating refractive index anisotropy, accounting for this phenomenon. This finding provides novel insights into the development of ultrafast acousto-optic devices.

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通过非对称 VO2/TiO2 异质结构的强相干声子工程实现双折射调制

光学晶体双折射的超快调制涉及晶格的快速变形，具有重要的科学和技术意义。高频相干声子通过对晶格秩序的瞬时扰动，已成为改变材料特性的有力工具。在这里，我们系统地研究了 VO/TiO 异质结构不对称晶向 [011]、[110] 和 [100] 中的相干声子。值得注意的是，在(011)-VO/TiO 体系中，激发了一个显著的剪切模式相干声子信号，与纵向模式相比，强度略高。通过改变探针光的偏振，我们观察到巨相干声子诱导的双折射符号发生了奇妙的逆转。密度泛函理论（DFT）计算表明，氧化钛具有出色的光弹性特性，强相干声子能有效调节折射率各向异性，从而解释了这一现象。这一发现为开发超快声光器件提供了新的见解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Materials Today Physics Materials Science-General Materials Science

CiteScore

14.00

自引率

7.80%

发文量

284

审稿时长

15 days

期刊介绍： Materials Today Physics is a multi-disciplinary journal focused on the physics of materials, encompassing both the physical properties and materials synthesis. Operating at the interface of physics and materials science, this journal covers one of the largest and most dynamic fields within physical science. The forefront research in materials physics is driving advancements in new materials, uncovering new physics, and fostering novel applications at an unprecedented pace.