基于紫外激光的羟基-平面激光诱导荧光探测研究进展

张仲磷; 杨岸龙; 王江; 程光华

doi:10.37188/CO.2024-0013

基于紫外激光的羟基-平面激光诱导荧光探测研究进展

doi: 10.37188/CO.2024-0013

1.
西北工业大学光电与智能研究院, 陕西西安 710072
2.
西安航天动力研究所航天液体动力全国重点实验室, 陕西西安 710100

基金项目: 国家重点研发计划（No. 2022YFB4600201）

详细信息

作者简介:
张仲磷（1996—），男，甘肃定西人，博士研究生，2018年于西安电子科技大学获得学士学位，2020年于哈尔滨工程大学获得硕士学位，主要从事固体激光器设计方面的研究。E-mail：zhangzhonglin@mail.nwpu.edu.cn

程光华（1976—），男，陕西安康人，博士，教授，博士生导师，1999年于西北大学获得学士学位，2004年于中国科学院西安光学精密机械研究所获博士学位，主要从事超短脉冲激光技术、超快激光于物质相互作用、飞秒激光微纳加工技术研究。E-mail：guanghuacheng@nwpu.edu.cn

中图分类号: TP394.1;TH691.9
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出版历程
- 收稿日期: 2024-01-15
- 修回日期: 2024-01-30
- 录用日期: 2024-03-25
- 网络出版日期: 2024-04-13

Research progress of hydroxy-plane laser-induced fluorescence detection based on ultraviolet laser

1.
School of Artificial Intelligence, Optics and Electronics, Northwestern Polytechnical University, Xi’an 710072, China
2.
National Key Laboratory of Aerospace Liquid Propulsion, Xi’an Aerospace Propulsion Institute, Xi’an 710100, China

Funds: Supported by the National Key Research and Development Program of China (No. 2022YFB4600201)

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Corresponding author: guanghuacheng@nwpu.edu.cn

摘要

摘要:
羟基(OH)是一种广泛存在于燃烧反应过程中的产物，在燃烧诊断技术中，基于羟基的二维空间分布常用于表征火焰的锋面结构，同时羟基也是表征火焰温度、火焰面密度和热释放速率等特征的重要参数。对燃烧火焰中的羟基进行有效探测是探究燃烧动力学演变过程，揭示火焰随机事件产生机理的重要支撑。平面激光诱导荧光(PLIF)技术作为一种光学测量方法，具有时空分辨率高、无干扰、可进行组份选择等优点，已成功用于对本生灯火焰、湍流火焰、旋流火焰和超声速火焰等多种燃烧火焰进行结构观测，为建立燃烧模型提供了重要参考。本文从PLIF探测的基本原理开始，梳理了PLIF技术在燃烧诊断领域的发展历程和研究现状，介绍了基于染料激光、光参量振荡和钛宝石三倍频方式实现的PLIF紫外光源技术，并对不同技术路线的特点进行了讨论，最后对用于OH-PLIF的紫外激光技术发展进行了展望。
- 燃烧 /
- 平面激光诱导荧光 /
- 激光 /
- 羟基
Abstract:
Hydroxyl (OH) is a widely existing product in the combustion reaction process. In combustion diagnosis technology, the two-dimensional spatial distribution based on hydroxyl is commonly used to characterize the structure of the flame front. Hydroxyl is an important parameter in characterizing the flame temperature, flame surface density, and heat release rate. The effective detection of hydroxyl in combustion flame is an important support for exploring the evolution of combustion dynamics and revealing the mechanism of random flame events. Planar laser-induced fluorescence (PLIF) has several advantages as an optical measurement method: high spatial and temporal resolution, non-intrusiveness, and component selection. PLIF has successfully observed the structure of various combustion flames, such as Bunsen burner flame, turbulent flame, swirl flame, and supersonic flame, which provides an important reference for establishing combustion models. This paper starts with the basic principle of PLIF detection, followed by the development history and research status of PLIF technology in the field of combustion diagnosis. Then, it introduces the PLIF ultraviolet light source technology based on dye laser, optical parametric oscillation, and Ti:sapphire tripling-frequency, and discusses the characteristics of different technical routes. Finally, it prospects the development of UV laser technology for OH-PLIF.
- combustion /
- planar laser-induced fluorescence /
- laser /
- Hydroxyl

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图 1 平面激光诱导荧光成像原理图

Figure 1. Schematic diagram of planar laser induced fluorescence imaging

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图 2 OH/丙酮-PLIF/PIV测量结果。(a)平均速度矢量及(b)OH-PLIF瞬时图像^[29]

Figure 2. Measurement results of OH/acetone-PLIF/PIV. (a) Mean velocity vectors and (b) instantaneous OH-PLIF image^[29]

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图 3 丙酮-PLIF在旋转爆震发动机的径向图^[30]

Figure 3. Radial diagram of acetone-PLIF in a rotating detonation engine^[30]

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图 4 OH与CH-PLIF在流向截面的火焰结构成像对比^[33]

Figure 4. Comparison of OH-PLIF and CH-PLIF images in a cavity-stabilized scramjet combustor^[33]

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图 5 1-8个大气压贫预混天然气火焰OH测量装置示意图^[18]

Figure 5. Schematic diagram of experimental set-up for OH measurement of 1-8 atmospheres lean premixed natural gas flames^[18]

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图 6 PLIF-PIV湍流射流举升火焰测量示意图。(a)实验装置；(b)射流燃烧器；(c)成像区域^[44]

Figure 6. Schematic diagram of PLIF-PIV turbulent jet lift flame measurement. (a) Experimental setup; (b) jet burner; (c) imaging region^[44]

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图 7 50 kHz高速OH-PLIF系统^[47]

Figure 7. High-speed OH-PLIF system with refrequency of 50 kHz^[47]

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图 8 20 kHz、CH₂O -PLIF/PIV实验装置^[48]

Figure 8. 20 kHz, CH₂O -PLIF/PIV experimental setup^[48]

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图 9 Burst模式实验装置及测量结果^[50]。 (a) 7.5 kHz、OH/CH₂O -PLIF实验装置；(b) 355 nm激光能量稳定性；(c) 283 nm激光能量稳定性

Figure 9. Burst mode experimental setup and measurement results^[50]. (a) 7.5 kHz, OH/CH₂O-PLIF experimental setup; pluse energy residuals for (b) 355 nm and (c) 283 nm pluse

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图 10 10 kHz 双平面PIV和OH-PLIF实验装置图^[51]。(a)实验光路布局图；(b)燃烧器光路鸟瞰图

Figure 10. Diagram of the 10 kHz biplane PIV and OH-PLIF experimental setups^[51]. (a) Layout of experimental optical path; (b) aerial view of light path of the burner

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图 11 OPO紫外激光实验装置^[52]

Figure 11. OPO Ultraviolet laser experimental equipment^[52]

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图 12 种子注入burst模式OPO紫外激光实验装置^[53]

Figure 12. Experimental setup for seed injection of burst-mode OPO UV lasers^[53]

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图 13 基于OPO和倍频方式的50 kHz重频PLIF实验装置^[54]

Figure 13. Experimental setup for 50 kHz PLIF based on OPO and frequency doubling method^[54]

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图 14 超高速OH/CH₂O-PLIF探测系统^[55]

Figure 14. Schematic diagram of experimental setup for ultra-high-speed simultaneous OH and CH₂O-PLIF^[55]

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图 15 三臂Burst模式激光系统^[56]

Figure 15. Schematic of the three-legged burst-mode laser system^[56]

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图 16 高速OH-PLIF实验装置示意图。(a) MHz泵浦源光路^[57]；(b)基于OPO-burst OH-PLIF的旋转爆震燃烧实验装置^[57]；(c) OPO光路图^[58]

Figure 16. Schematic diagram of the high-speed OH-PLIF experimental setup. (a) MHz pump source optical path^[57]; (b) OPO-burst OH-PLIF based rotary burst combustion experimental setup; (c) OPO optical path diagram^[58]

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图 17 飞秒OH-PLIF探测装置^[59]

Figure 17. Femtosecond OH-PLIF detector^[59]

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图 18 钛宝石OH-PLIF实验装置。(a)基于钛宝石三倍频实现的283 nm紫外激光器；(b)本生灯探测结果^[60]

Figure 18. OH-PLIF experiment setup with Ti: sapphire. (a) 283 nm UV laser based on titanium gemstone triplex realisation; (b) Bunsen burner detection results^[60]

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表 1 用于OH-PLIF的紫外激光器性能对比

Table 1. Performance Comparison of UV Lasers for OH-PLIF

Year	Operation mode	Repetition frequency	Wavelength	Output power	Pulse energy	Conversion efficiency
2007^[18]	Rhodamine +SHG	10 Hz	283.92 nm	0.06 W	6 mJ	-
2007^[43]	Rhodamine 5G+BBO SHG	2.5 kHz 5 kHz	283 nm	130 mW 110 mW	50 μJ 22 μJ	0.7% 0.6%
2009^[44]	Rhodamine 6G+SHG	1.5 kHz	283 nm	0.82 W	0.54 mJ	1.6%
2009^[45]	Rhodamine 6G+BBO SHG	5 kHz	283.2 nm	0.5 W	100 μJ	2.6%
2010^[46]	Rhodamine 6G+BBO SHG	10 kHz	283.2 nm	1.4 W	140 μJ	3.5%
2014^[47]	Rhodamine 6G+2*BBO SHG+MOPA	50 kHz	283 nm	7 W	0.14 mJ	3.5%
2018^[48]	Burst/Rhodamine 6G+SHG	20 kHz	283 nm	1.8 W	90 μJ	2.8%
2018^[49]	Burst/Rhodamine 6G+MOPA+BBO SHG	7.5 kHz	282.985 nm	16.5 W	2.2 mJ	-
2018^[11]	Rhodamine 590+SHG	-	283 nm	-	12 mJ	-
2020^[51]	Dye laser+SHG	10 kHz	283.9 nm	1.6 W	0.16 mJ	-
2009^[52]	Burst/Seeding OPO+BBO SHG	-	282.97 nm	0.2 W	-	-
2017^[53]	Burst/Seeding OPO+BBO SFG	10 kHz	284.005 nm	-	3 mJ	-
2017^[54]	Burst/Multi-YAG+OPO+SHG	50 kHz	283 nm	-	2 mJ	1.25%
2017^[55]	Burst/OPO+BBO SHG	50 kHz	284 nm	-	350 μJ	0.7%
2018^[56]	OPO+SFG	10 kHz	284 nm	-	5 mJ	0.7%
2020^[58]	Burst/Seeding OPO+BBO SFG	1 MHz	284 nm	-	400 μJ	0.6%
2020^[59]	fs Ti:sapphire+ BBO THG	1 kHz	283 nm	-	90 μJ	4.5%
2023^[60]	ns Ti:sapphire+LBO SHG+BBO THG	1 kHz	283 nm	0.56 W	0.56 mJ	2.8%

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