Single-shot single-beam coherent Raman scattering thermometry based on optically induced air lasing

IF 20.6 Q1 OPTICS Light-Science & Applications Pub Date : 2024-11-25 DOI:10.1038/s41377-024-01598-9

Xu Lu, Yewei Chen, Francesco Mazza, Siyi He, Zihan Li, Shunlin Huang, Quanjun Wang, Ning Zhang, Bo Shen, Yuzhu Wu, Jinping Yao, Ya Cheng

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Abstract

Thermometric techniques with high accuracy, fast response and ease of implementation are desirable for the study of dynamic combustion environments, transient reacting flows, and non-equilibrium plasmas. Herein, single-shot single-beam coherent Raman scattering (SS-CRS) thermometry is developed, for the first time to our knowledge, by using air lasing as a probe. We show that the air-lasing-assisted CRS signal has a high signal-to-noise ratio enabling single-shot measurements at a 1 kHz repetition rate. The SS-CRS thermometry consistently exhibits precision of <2.3% at different temperatures, but the inaccuracy grows with the increase in temperature. The high measurement repeatability, 1 kHz acquisition rate and easy-to-implement single-beam scheme are achieved thanks to the unique temporal, spectral and spatial characteristics of air lasing. This work opens a novel avenue for high-speed CRS thermometry, holding tremendous potential for fast diagnostics of transient reacting flows and plasmas.

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基于光诱导空气激光的单光束相干拉曼散射测温技术

在研究动态燃烧环境、瞬态反应流和非平衡态等离子体时，需要高精度、快速响应和易于实施的测温技术。在此，我们首次利用空气激光作为探针，开发了单射单束相干拉曼散射（SS-CRS）测温技术。我们的研究表明，空气激光辅助的相干拉曼散射信号具有很高的信噪比，能以 1 kHz 的重复频率进行单次测量。在不同温度下，SS-CRS 测温仪的精度始终保持在 2.3%，但不准确度会随着温度的升高而增加。由于空气激光具有独特的时间、光谱和空间特性，因此可以实现高测量重复性、1 kHz 采集率和易于实施的单光束方案。这项工作为高速 CRS 测温开辟了一条新途径，为瞬态反应流和等离子体的快速诊断带来了巨大潜力。

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