Novel synthesis and design methods of optical thin film structures using vanadium dioxide phase change material

International Workshop on Thin Films for Electronics, Electro-Optics, Energy and Sensors Pub Date : 2019-12-06 DOI:10.1117/12.2535617

A. Sarangan

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Abstract

Recent developments in phase change materials have led to a new generation of electronic and photonic memory devices and thermally tunable devices. Vanadium dioxide (VO2) and Germanium Antimoy Telluride (GST) are two of the most developed phase change materials. The focus of this work is on vanadium dioxide. Current methods of growing vanadium dioxide rely on reactive physical vapor deposition on heated and lattice-matched substrates. This is often a difficult deposition process with a very narrow process window. The high process tem- peratures, patterning and etching challenges, and the lattice-matching requirement severely limit the number of materials VO2 can co-exist with. As a result, compared to other types of inorganic optical thin film materials, the development of practical devices exploiting VO2 has been modest. In this paper, novel and simplified approaches to producing VO2 thin films is discussed, especially in regards to creating multilayer optical structures, tunable optical filters, switchable wiregrid polarizers, and tunable Bragg reflectors. The growth and characterization of nanostructured VO2 films are also discussed.

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利用二氧化钒相变材料制备光学薄膜结构的新方法

相变材料的最新发展导致了新一代的电子和光子存储器件以及热可调谐器件。二氧化钒(VO2)和碲化锑锗(GST)是两种最发达的相变材料。这项工作的重点是二氧化钒。目前的二氧化钒生长方法依赖于在加热和晶格匹配的衬底上的反应性物理气相沉积。这通常是一个困难的沉积过程，过程窗口非常窄。高工艺温度、图像化和蚀刻挑战以及晶格匹配要求严重限制了VO2可以共存的材料数量。因此，与其他类型的无机光学薄膜材料相比，利用VO2的实用器件的发展一直是适度的。本文讨论了新的和简化的方法来生产VO2薄膜，特别是关于创建多层光学结构，可调谐的光学滤波器，可切换的线栅偏振器和可调谐的布拉格反射器。本文还讨论了纳米结构VO2薄膜的生长和表征。

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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International Workshop on Thin Films for Electronics, Electro-Optics, Energy and Sensors

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