Sensing of ultrasonic fields based on polarization parametric indirect microscopic imaging

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英文篇名：Sensing of ultrasonic fields based on polarization parametric indirect microscopic imaging 作者：曹云 ; 熊吉川 ; 刘学峰 ; 夏志颖 ; 王惟泽 ; N.P.Yadav ; 刘卫平 英文作者：Yun Cao;Jichuan Xiong;Xuefeng Liu;Zhiying Xia;Weize Wang;N.P.Yadav;Weiping Liu;School of Electronic and Optical Engineering, Nanjing University of Science and Technology; 中文刊名：GXKB 英文刊名：中国光学快报(英文版) 机构：School of Electronic and Optical Engineering, Nanjing University of Science and Technology; 出版日期：2019-04-25 出版单位：Chinese Optics Letters 年：2019 期：v.17 基金：supported by the National Key Research and Development Program of China(No.2017YFF0107100);; the National Natural Science Foundation of China(NSFC)(Nos.61501239 and 51805268);; the NSFC International Young Scientist Research Fund(No.61750110520);; China Postdoctoral Science Foundation(No.2017M621745);; Overseas Expertise Introduction Project for Discipline Innovation(111 Project);; Zijin Professor Project of Nanjing University of Science and Technology 语种：英文; 页：GXKB201904018 页数：6 CN：04 ISSN：31-1890/O4 分类号：93-98

摘要

This Letter tackles the issue of non-contact detection of ultrasonic fields by utilizing a novel optical method based on the parametric indirect microscopic imaging(PIMI) technique. A general theoretical model describing the three-dimensional anisotropic photoelastic effect in solid was developed. The mechanism of polarization status variations of light passing through the stress and strain fields was analyzed. Non-contact measurements of the ultrasonic field propagating in an isotropic quartz glass have been fulfilled by the PIMI technique under different ultrasonic excitation conditions. PIMI parameters such as sin δ, Φ, and the Stokes parameters have been found to be sensitive to ultrasonic fields.
        This Letter tackles the issue of non-contact detection of ultrasonic fields by utilizing a novel optical method based on the parametric indirect microscopic imaging(PIMI) technique. A general theoretical model describing the three-dimensional anisotropic photoelastic effect in solid was developed. The mechanism of polarization status variations of light passing through the stress and strain fields was analyzed. Non-contact measurements of the ultrasonic field propagating in an isotropic quartz glass have been fulfilled by the PIMI technique under different ultrasonic excitation conditions. PIMI parameters such as sin δ, Φ, and the Stokes parameters have been found to be sensitive to ultrasonic fields.

引文

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