Ultrasound detection using a thermal-assisted microcavity Raman laser

Jia-Wei Meng, Pei-Ji Zhang, Shui-Jing Tang, Yun-Feng Xiao
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引用次数: 0

Abstract

Optical microcavities have emerged as promising platforms for ultrasound detection. One of the main tendencies in recent studies is to develop high-Q microresonators for ultrasensitive ultrasound detection, while the nonlinear optical effects become significant but are generally neglected. Here, we propose a thermal-assisted microcavity Raman laser for ultrasound detection. Acoustic waves modulate the resonant frequency of the cavity mode, altering the coupled efficiency of a fixed-wavelength input laser, and therefore the output Raman power. Experimentally, the noise equivalent pressure reaches as low as 8.1 Pa at 120 kHz in air. Besides, it is found that the thermal effect involved in high-Q microcavities can compensate for the low-frequency noises, while without degrading their sensitivity to high-frequency acoustic waves above hundreds of kilohertz. Therefore, it enables long-standing stability during the measurements due to the natural resistance to laser frequency drifts and environmental disturbances, which holds great potential in practical applications of ultrasound sensing and imaging.

使用热辅助微腔拉曼激光器进行超声波探测
光学微腔已成为超声波探测的理想平台。近期研究的主要趋势之一是开发用于超灵敏超声检测的高 Q 值微谐振器,而非线性光学效应变得非常重要,但通常被忽视。在此,我们提出了一种用于超声检测的热辅助微腔拉曼激光器。声波调制腔模式的谐振频率,改变固定波长输入激光器的耦合效率,从而改变输出拉曼功率。实验结果表明,在空气中 120 kHz 时,噪声等效压力低至 8.1 Pa。此外,研究还发现,高 Q 值微腔中的热效应可以补偿低频噪声,同时不会降低其对数百千赫兹以上高频声波的灵敏度。因此,高 Q 值微腔具有天然的抗激光频率漂移和环境干扰能力,可在测量过程中保持长期稳定性,在超声波传感和成像的实际应用中具有巨大潜力。
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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CiteScore
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