Photonic and Optomechanical Thermometry

3区 物理与天体物理 Q1 Materials Science Progress in Optics Pub Date : 2022-04-29 DOI:10.3390/opt3020017
T. Briant, S. Krenek, Andrea Cupertino, F. Loubar, R. Braive, L. Weituschat, Daniel Ramos, M. J. Martin, P. Postigo, Alberto Casas, R. Eisermann, D. Schmid, Shahin Tabandeh, O. Hahtela, Sara Pourjamal, O. Kozlova, S. Kroker, W. Dickmann, L. Zimmermann, G. Winzer, T. Martel, P. Steeneken, R. Norte, S. Briaudeau
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Abstract

Temperature is one of the most relevant physical quantities that affects almost all processes in nature. However, the realization of accurate temperature standards using current temperature references, like the triple point of water, is difficult due to the requirements on material purity and stability of the environment. In addition, in harsh environments, current temperature sensors with electrical readout, like platinum resistors, are difficult to implement, urging the development of optical temperature sensors. In 2018, the European consortium Photoquant, consisting of metrological institutes and academic partners, started investigating new temperature standards for self-calibrated, embedded optomechanical sensor applications, as well as optimised high resolution and high reliability photonic sensors, to measure temperature at the nano and meso-scales and as a possible replacement for the standard platinum resistant thermometers. This article presents an overview of the results obtained with sensor prototypes that exploit photonic and optomechanical techniques for sensing temperatures over a large temperature range (5 K to 300 K). Different concepts are demonstrated, including ring resonators, ladder-like resonators and suspended membrane optomechanical thermometers, highlighting initial performance and challenges, like self-heating that need to be overcome to realize photonic and optomechanical thermometry applications.
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光子和光机械测温
温度是影响自然界几乎所有过程的最相关的物理量之一。然而,由于对材料纯度和环境稳定性的要求,使用当前的温度参考来实现精确的温度标准(如水的三相点)是困难的。此外,在恶劣环境下,与铂电阻一样具有电读出的电流温度传感器难以实现,这促使光学温度传感器的发展。2018年,由计量研究所和学术合作伙伴组成的欧洲财团Photoquant开始研究自校准嵌入式光机械传感器应用的新温度标准,以及优化的高分辨率和高可靠性光子传感器,以测量纳米和中观尺度的温度,并可能取代标准的耐铂温度计。本文概述了利用光子和光机械技术在大温度范围内(5 K至300 K)感应温度的传感器原型所获得的结果。展示了不同的概念,包括环形谐振器、阶梯状谐振器和悬浮膜光机械温度计,突出了初始性能和挑战,如实现光子和光机械测温应用需要克服的自热。
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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来源期刊
Progress in Optics
Progress in Optics 物理-光学
CiteScore
4.50
自引率
0.00%
发文量
8
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