High-Q GRIN resonators

SPIE LASE Pub Date : 2016-04-22 DOI:10.1117/12.2214409

A. Armani, S. Soltani, Hyungwoo Choi, V. Diep, A. Kovach, K. Kuo

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Abstract

High and ultra-quality factor (Q) optical resonators have been used in numerous applications, ranging from biodetection and gyroscopes to nonlinear optics. In the majority of the measurements, the fundamental optical mode is used as it is easy to predict its behavior and subsequent response. However, there are numerous other modes which could give improved performance or offer alternative measurement opportunities. For example, by using a mode located farther from the device surface, the optical field becomes less susceptible to changes in the environment. However, selectively exciting a pre-determined, non-fundamental mode or, alternatively, creating a “designer” mode which has one’s ideal properties is extremely challenging. One approach which will be presented is based on engineering a gradient refractive index (GRIN) cavity. We use a silica ultra-high-Q toroidal cavity as a starting platform device. On top of this structure, we can controllably deposit, layer or grow different materials of different refractive indices, with nm-scale precision, creating resonators with a GRIN region co-located with the optical field. Slight adjustments in the thicknesses or indices of the films result in large changes in the mode which is most easily excited. Even in this architected structure, we have maintained Q>1 million. Using this approach, we have demonstrated the ability to tune the properties of the device. For example, we have changed the thermal response and the UV response of a device by over an order of magnitude.

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高q GRIN谐振器

高质量因子和超高质量因子(Q)光学谐振器已被广泛应用，从生物检测和陀螺仪到非线性光学。在大多数测量中，基本光学模式被使用，因为它很容易预测其行为和随后的响应。然而，还有许多其他模式可以提高性能或提供替代测量机会。例如，通过使用远离设备表面的模式，光场变得不太容易受到环境变化的影响。然而，有选择地激发一个预先确定的、非基本的模式，或者创造一个具有理想属性的“设计师”模式，都是极具挑战性的。其中一种方法是基于工程的梯度折射率(GRIN)腔。我们使用硅超高q环形腔作为启动平台装置。在这种结构之上，我们可以以纳米级精度可控地沉积、分层或生长不同折射率的不同材料，创造出与光场共存的GRIN区域的谐振器。薄膜的厚度或指数的轻微调整会导致最容易被激发的模式发生很大变化。即使在这个建筑结构中，我们也保持了100万英镑。使用这种方法，我们已经演示了调整设备属性的能力。例如，我们已经将器件的热响应和紫外响应改变了一个数量级以上。

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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