原文地址:http://news.sciencenet.cn/htmlnews/2023/11/512038.shtm
直播时间:2023年11月10日(周五)20:00-21:30
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北京时间2023年11月10日晚八点,iCANX Talks 第169期邀请到圣路易斯华盛顿大学的杨兰教授进行分享!更多精彩,敬请期待!
【嘉宾介绍】
Lan Yang
Washington University in St. Louis
Whispering-gallery-mode optical resonators: a versatile platform for fundamental science and applications
【Abstract】
In the past decade, there has been rapid progress in the field of optical resonators, which have been demonstrated as a versatile platform for exploring both fundamental science and technology advancements, ranging from applications in biosensing to the development of narrow-linewidth lasers and microcombs. Among these, whispering-gallery-mode (WGM) optical resonators have emerged as a frontrunner that stands out in enhancing light-matter interactions, leading to numerous groundbreaking discoveries. I will start the talk with a brief review of the history of WGM resonators. Throughout the presentation, I will showcase several examples demonstrating the great potential of high-quality (Q) WGM microresonators and microlasers for fundamental science and engineering applications. In particular, I will discuss the recent exploration of fundamental physics associated with non-Hermitian physics, including intriguing concepts such as parity-time symmetry (PT-symmetry) and light-matter interactions around an exceptional point (EP), in high-quality WGM resonators. These experiments, initially implemented within the context of resonators, have the potential to shape innovative strategies that will pave the way for a new generation of optical systems, enabling unconventional control of light flow. Non-Hermitian physics will be presented as an guideline to design resonator structures with new physical behavior and innovative functionality. Several examples will be presented, including nonreciprocal light transmission, loss engineering in a lasing system, chiral modes at exceptional points (EPs) for directional lasing emission, EPs enhanced sensing, and chiral EP-assisted electromagnetically induced transparency (EIT). In conclusion, I will envision exciting opportunities for WGM resonators enabled by integrated photonics. These opportunities hold great promise for advancing the field of photonics and opening up new horizons for optical technologies.
在过去的十年中,光学谐振腔领域取得了迅猛的进展,已被证明是一个多用途的平台:从生物传感到窄线宽激光和微型光梳等技术进步以及基础科学的各种应用,其中回音廊模(WGM)光学谐振腔作为领跑者,突显出在增强光-物质相互作用方面的出色表现,引领了众多的突破性发现。杨兰教授将从WGM谐振腔的历史简要回顾开始演讲。在整个演示过程中,杨兰教授将展示几个示例,展示高品质(Q)WGM微谐振腔和微激光器在基础科学和工程应用中的巨大潜力。特别讨论与非厄米物理相关的基础物理的最新探索,包括有趣的概念,宇称-时间对称性(PT-对称性)和高品质WGM谐振腔中异常点(EP)周围的光-物质相互作用。这些实验最初在谐振腔的背景下实施,但是它有潜力提供创新策略为新一代光学系统铺平道路,实现对光流的非传统控制。非厄米物理被提出来作为设计具有新物理行为和创新功能的谐振腔结构的一个方案。报告将讨论多个示例,包括非互易光传输,激光系统中的损耗调控,异常点(EPs)处的手性模式用于定向激光辐射,增强传感的异常点(EPs)以及手性EP辅助电磁感应透明(EIT)。最后展望由集成光子学带来的WGM谐振腔的激动人心机遇。这些机会将有望推动光子学领域的发展,为光学技术开辟新的前景。
【BIOGRAPHY】
Professor Lan Yang is the Edwin H. and Florence G. Skinner professor in the Preston M. Green Department of Electrical and Systems Engineering at Washington University in St. Louis. She is also the editor-in-chief of Photonics Research. She received a B.S. from the University of Science and Technology of China and completed her Ph.D. in applied physics at Caltech in 2005. Her research interests have been focusing on the fundamental understanding of light-matter interactions and their applications. She enjoys investigating physics in various high-quality photonic resonators and exploring their diverse applications, including lasing, communication, quantum technologies, sensing, and imaging, etc. Her research in parity-time-symmetry and non-Hermitian physics in high-quality resonators has led to a series of discoveries for unconventional control of light transport in photonic structures. She received the NSF CAREER Award in 2010 for her work on single nanoparticle detection and sizing using an on-chip optical resonator. She also received the 2010 Presidential Early Career Award for Scientists and Engineers (PECASE). She is a Fellow of OSA (Optical Society of America), IEEE (Institute of Electrical and Electronics Engineers), APS (American Physical Society), and AAAS (American Association for the Advancement of Science). She has been recognized as one of the highly cited researchers by Clarivate each year since 2019. She shared her experiences in a Mid-America Emmy award-winning short film in 2020 titled “Changing the World Through Science: Lan Yang”. This film captures her dedication, perseverance, and passion for science.
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