基于连续体束缚态的高性能传感器

Guodong Zhu, Sen Yang, J. Ndukaife
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引用次数: 0

摘要

连续统中的束缚态是由量子力学中的冯·诺伊曼和维格纳首次发现的。它随后在光子学中被发现。BIC代表了一种可以完美地限制光的嵌入式特征模。支持这种模式的光学谐振器理论上可以有非常大的场增强和无限的Q因子。考虑到这些优点以及可以忽略不计的热量产生,使用BIC模式的介电超表面是一个更有前途的传感器应用平台。然而,它们的性能受到诸如不可避免的制造缺陷、芯片阵列尺寸和上下对称破坏等因素的限制。为了缓解这些挑战,我们在Lieb晶格中构造了具有可达电场分布的合并bic。同时,我们将该系统与横向光子晶体反射镜集成在一起,以提高其在紧凑条件下的性能。我们提出的设计保持稳健,即使在上下对称被打破时也能保持非常高的Q因子(高达105),这为光学捕获和生物医学传感应用提供了一个潜在的平台。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
High-performance sensor based on bound states in the continuum
The bound states in the continuum (BIC) were first discovered by von Neumann and Wigner in quantum mechanics. It was subsequently identified in photonics. BIC represents an embedded eigenmode that can perfectly confine light. The optical resonators that support this mode can have very large field enhancements and infinite Q factor in theory. Considering these advantages as well as the negligible heat generation, the dielectric metasurface using BIC mode is a more promising platform for sensor applications. Nevertheless, their performance is quite constrained by factors such as inevitable fabrication imperfections, the array size of chips, and up-down symmetry breaking. To mitigate these challenges, we construct merging BICs with the accessible electric field distribution in a Lieb lattice. Meanwhile, we integrated this system with a lateral photonic crystal mirror to enhance its performance in compact conditions. The design we propose remains robust, sustaining a very high Q factor (up to 105) even when the up-down symmetry is broken, which provides a potential platform for optical trapping and biomedical sensing applications.
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