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Autori principali: Suebka, Sartanee, McLeod, Euan, Su, Judith
Natura: Preprint
Pubblicazione: 2023
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Accesso online:https://arxiv.org/abs/2308.00726
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author Suebka, Sartanee
McLeod, Euan
Su, Judith
author_facet Suebka, Sartanee
McLeod, Euan
Su, Judith
contents Whispering gallery mode (WGM) microtoroid resonators are one of the most sensitive biochemical sensors in existence, capable of detecting single molecules. The main barrier for translating these devices out of the laboratory is that light is evanescently coupled into these devices though a tapered optical fiber. This hinders translation of these devices as the taper is fragile, suffers from mechanical vibration, and requires precise positioning. Here, we eliminate the need for an optical fiber by coupling light into and out from a toroid via free-space coupling and monitoring the scattered resonant light. A single long working distance objective lens combined with a digital micromirror device (DMD) was used for light injection, scattered light collection, and imaging. We obtain Q-factors as high as $1.6 \times 10^8$ with this approach. Electromagnetically induced transparency (EIT)-like and Fano resonances were observed in a single cavity due to indirect coupling in free space. This enables improved sensing sensitivity. The large effective coupling area (~10 $μ$m in diameter for numerical aperture = 0.14) removes the need for precise positioning. Sensing performance was verified by combining the system with the frequency locked whispering evanescent resonator (FLOWER) approach to perform temperature sensing experiments. We believe that this work will be a foundation for expanding the implementation of WGM microtoroid resonators to real-world applications.
format Preprint
id arxiv_https___arxiv_org_abs_2308_00726
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Ultra-high-Q free space coupling to microtoroid resonators
Suebka, Sartanee
McLeod, Euan
Su, Judith
Optics
Whispering gallery mode (WGM) microtoroid resonators are one of the most sensitive biochemical sensors in existence, capable of detecting single molecules. The main barrier for translating these devices out of the laboratory is that light is evanescently coupled into these devices though a tapered optical fiber. This hinders translation of these devices as the taper is fragile, suffers from mechanical vibration, and requires precise positioning. Here, we eliminate the need for an optical fiber by coupling light into and out from a toroid via free-space coupling and monitoring the scattered resonant light. A single long working distance objective lens combined with a digital micromirror device (DMD) was used for light injection, scattered light collection, and imaging. We obtain Q-factors as high as $1.6 \times 10^8$ with this approach. Electromagnetically induced transparency (EIT)-like and Fano resonances were observed in a single cavity due to indirect coupling in free space. This enables improved sensing sensitivity. The large effective coupling area (~10 $μ$m in diameter for numerical aperture = 0.14) removes the need for precise positioning. Sensing performance was verified by combining the system with the frequency locked whispering evanescent resonator (FLOWER) approach to perform temperature sensing experiments. We believe that this work will be a foundation for expanding the implementation of WGM microtoroid resonators to real-world applications.
title Ultra-high-Q free space coupling to microtoroid resonators
topic Optics
url https://arxiv.org/abs/2308.00726