High-speed laser-absorption measurements of non-equilibrium nitric oxide in the Sandia Hypersonic Shock Tunnel

IF 2 3区 物理与天体物理 Q3 OPTICS Applied Physics B Pub Date : 2024-10-23 DOI:10.1007/s00340-024-08330-w
Jonathan J. Gilvey, Elijah R. Jans, Kyle A. Daniel, Charley R. Downing, Bradley T. Lyon, Kyle P. Lynch, Justin L. Wagner, Christopher S. Goldenstein
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Abstract

This manuscript presents a quantum-cascade-laser-absorption-spectroscopy (QCLAS) diagnostic for the partial pressure and internal temperatures (rotational and vibrational) of nitric oxide (NO) in hypersonic flows. Two quantum-cascade lasers (QCLs) were used to measure four transitions of NO near 1887 cm\(^{-1}\) and 1930 cm\(^{-1}\) at 25 or 100 kHz using scanned-wavelength direct absorption. Tests were performed in the Purdue High-Pressure Shock Tube (HPST) using an NO–Ar mixture to confirm the accuracy of the diagnostic. The diagnostic was then applied to characterize the Hypersonic Shock Tunnel (HST) at Sandia National Laboratories. In the HST, two flow cutters were used to direct the measurement line-of-sight through the quasi-uniform core flow exiting the nozzle, thereby avoiding measurement complications associated with the thick boundary layers at the nozzle exit. In the HST, tests were performed with air velocities of 3, 4, and 5 km/s where the rotational and vibrational temperature of NO varied from 150 to 850 K and the partial pressure of NO was near 20 Pa. Additionally, dry bottled air and humid room air were used as test gases to quantify the impact of water contamination on the vibrational non-equilibrium of NO. Comparisons with two CFD predictions using unique rate constants for vibrational relaxation are also presented. The vibrational non-equilibrium of NO was more pronounced for 3 km/s tests, and water had a negligible impact on the thermal non-equilibrium of NO. Lastly, the measured rotational temperature of NO agreed well with CFD predictions, the measured partial pressure of NO was consistently above CFD predictions, and the vibrational temperature had moderate agreement with CFD predictions for 4 and 5 km/s tests, and poor agreement for 3 km/s tests.

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桑迪亚高超音速冲击隧道中对非平衡一氧化氮的高速激光吸收测量
本手稿介绍了一种量子级联激光吸收光谱(QCLAS)诊断方法,用于诊断高超音速气流中一氧化氮(NO)的分压和内部温度(旋转和振动)。利用两台量子级联激光器(QCL),在 25 或 100 kHz 频率下,使用扫描波长直接吸收法测量一氧化氮在 1887 cm\(^{-1}\) 和 1930 cm\(^{-1}\) 附近的四个跃迁。在普渡高压冲击管(HPST)中使用 NO-Ar 混合物进行了测试,以确认诊断的准确性。随后,该诊断方法被用于鉴定桑迪亚国家实验室的高超声速冲击隧道(HST)。在 HST 中,使用了两个流动切割器来引导测量视线穿过从喷嘴流出的准均匀核心流,从而避免了与喷嘴出口处厚边界层相关的测量复杂性。在 HST 中,测试在 3、4 和 5 千米/秒的气速下进行,氮氧化物的旋转和振动温度在 150 至 850 K 之间变化,氮氧化物的分压接近 20 Pa。此外,还使用干燥的瓶装空气和潮湿的室内空气作为测试气体,以量化水污染对 NO 振动非平衡的影响。此外,还介绍了与使用独特振动弛豫速率常数的两种 CFD 预测结果的比较。在 3 千米/秒的测试中,氮氧化物的振动非平衡更为明显,而水对氮氧化物热非平衡的影响可以忽略不计。最后,测得的 NO 旋转温度与 CFD 预测值吻合良好,测得的 NO 分压始终高于 CFD 预测值,4 和 5 千米/秒试验的振动温度与 CFD 预测值吻合适中,3 千米/秒试验的吻合度较差。
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来源期刊
Applied Physics B
Applied Physics B 物理-光学
CiteScore
4.00
自引率
4.80%
发文量
202
审稿时长
3.0 months
期刊介绍: Features publication of experimental and theoretical investigations in applied physics Offers invited reviews in addition to regular papers Coverage includes laser physics, linear and nonlinear optics, ultrafast phenomena, photonic devices, optical and laser materials, quantum optics, laser spectroscopy of atoms, molecules and clusters, and more 94% of authors who answered a survey reported that they would definitely publish or probably publish in the journal again Publishing essential research results in two of the most important areas of applied physics, both Applied Physics sections figure among the top most cited journals in this field. In addition to regular papers Applied Physics B: Lasers and Optics features invited reviews. Fields of topical interest are covered by feature issues. The journal also includes a rapid communication section for the speedy publication of important and particularly interesting results.
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