New phase change materials for active photonics

Cosmin Constantin-Popescu, M. Shalaginov, F. Yang, Hung-I Lin, S. An, Christopher M. Roberts, P. Miller, M. Kang, K. Richardson, Hualiang Zhang, C. Rivero‐Baleine, Hyun Jung Kim, T. Gu, S. Vitale, Juejun Hu
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引用次数: 1

Abstract

Phase change materials or PCMs are truly remarkable compounds whose unique switchable properties have fueled an explosion of emerging applications in electronics and photonics. Nonetheless, if we discount their use in optical discs, PCMs’ immense application potential in photonics beyond data recording has only begun to unfold in the past decade. While the material requirements for optical or electronic data storage have been succinctly summarized as five key elements “writability, archival storage, erasability, readability, and cyclability” decades ago, these requirements are not universally relevant to the diverse set of photonic applications now being explored. It also comes as no surprise that existing PCMs, which have been heavily vetted for data storage, are not necessarily the optimal compositions for different use cases in optics and photonics. PCMs with their attributes custom-tailored for specific applications are therefore in demand as phase-change photonics continue to expand. Here we discuss the PCM selection and design strategies specifically for photonic applications as well as our recent work developing active integrated photonic devices and meta-surface optics based on new PCMs tailored for photonics.
新型有源光子学相变材料
相变材料(pcm)是一种真正了不起的化合物,其独特的可切换特性推动了电子和光子学领域新兴应用的爆炸式增长。尽管如此,如果我们不考虑它们在光盘中的应用,pcm在光子学领域的巨大应用潜力在过去的十年中才刚刚开始展现。虽然光学或电子数据存储的材料要求在几十年前被简洁地概括为五个关键要素“可写性、存档存储性、可擦除性、可读性和可循环性”,但这些要求与现在正在探索的各种光子应用并不普遍相关。同样不足为奇的是,现有的pcm已经经过了严格的数据存储审查,并不一定是光学和光子学中不同用例的最佳组合。因此,随着相变光子学的不断发展,具有为特定应用定制属性的pcm受到了需求。在这里,我们讨论了专门针对光子应用的PCM选择和设计策略,以及我们最近开发的有源集成光子器件和基于为光子学量身定制的新型PCM的元表面光学。
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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