Simulation of light propagation in medium with an ultrasonically induced refractive index gradient

Journal of Applied Physics Pub Date : 2024-05-15 DOI:10.1063/5.0207446

Y. Harada, M. Ishikawa, Y. Kuroda, M. Matsukawa, D. Koyama

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Abstract

Modulation of the refractive index in a medium by external stimuli enables fast and reversible control of light propagation. This technology for controlling light has led to new discoveries in a wide range of research fields from physics to life sciences and has played a major role in the development of photonics devices. In this article, we focus on ultrasound as an external stimulus and have devised a method to control the refractive index of a medium using ultrasound. Our research group has previously discovered that a giant refractive-index gradient (Δn on the order of 10−2) was induced when water was irradiated with high-frequency (100 MHz range), high-intensity (on the order of MPa) ultrasound. Here, we report ray-tracing simulations in a medium with a refractive-index gradient induced by ultrasonic radiation. A numerical model of the refractive-index gradient was developed based on the experimental data, and ray-tracing simulations were performed using the Euler–Lagrange equation. The ray-tracing simulation results were close numerically to the profiles of the laser beam observed in the experiment when the laser beam was incident on the refractive-index-gradient medium.

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模拟光在具有超声诱导折射率梯度的介质中的传播

通过外部刺激调制介质的折射率可以快速、可逆地控制光的传播。这种控制光的技术已在从物理学到生命科学的广泛研究领域中带来了新发现，并在光子学设备的发展中发挥了重要作用。在这篇文章中，我们将重点放在作为外部刺激的超声波上，并设计了一种利用超声波控制介质折射率的方法。我们的研究小组以前曾发现，用高频率（100 兆赫范围）、高强度（兆帕量级）的超声波照射水时，会诱发巨大的折射率梯度（Δn 在 10-2 量级）。在此，我们报告了超声波辐射诱导折射率梯度介质的射线追踪模拟。根据实验数据建立了折射率梯度的数值模型，并使用欧拉-拉格朗日方程进行了射线追踪模拟。当激光束入射到折射率梯度介质上时，射线追踪模拟结果与实验中观察到的激光束轮廓非常接近。

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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Journal of Applied Physics

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