|
|
|
|
|
|
| Study on the Characteristics of Femtosecond Laser-Induced Cyano
Chemiluminescence Under Low-Pressure Environment |
| SHAN Yuan1, YAN Hao2, LIU Xu-hui2, HAN Lei1, LU Zheng1, LIU Zi-han1, LI Bo1, GAO Qiang1* |
1. State Key Laboratory of Engines, Tianjin University, Tianjin 300072, China
2. Beijing Institute of Control Engineering, Beijing 100190, China
|
|
|
|
|
Abstract Femtosecond laser molecular tagging velocimetry is currently the most mainstream non-intrusive velocimetric technique and is widely used in velocity field measurement in atmospheric pressure environments, especially having great advantages in supersonic and hypersonic flow field measurement. Currently, femtosecond laser molecular tagging velocimetry methods primarily include femtosecond laser electron excitation tagging velocimetry for tagging nitrogen molecules and femtosecond laser-induced cyano chemiluminescence velocimetry (FLICC) for tagging methane/nitrogen. Compared to femtosecond laser electron excitation tagging velocimetry, FLICC technology offers significant advantages in signal strength and duration, and its velocity measurement range and applicable scenarios have also been significantly expanded. This technology can provide technical support for flow velocity measurement in environments such as high-speed wind tunnels and aerospace propulsion systems. However, high-speed flow fields are often accompanied by low-pressure environments, such as those found in low-pressure wind tunnels on the ground, near-Earth, or in deep space. Therefore, it is of great significance to study flow field measurement technology in a low-pressure environment. Currently, the applicability of FLICC technology for velocity measurement in low-pressure environments remains undetermined. Since FLICC technology obtains velocity information by capturing the displacement of tagged luminescent molecules over a specific period, the intensity and duration of the tagged molecule's luminescence directly determine the feasibility of its application. In low-pressure environments, due to the decrease in particle number density, the interaction between the femtosecond laser and molecules, as well as the energy transfer between particles, is affected, thereby altering the intensity and lifetime of luminescence. The main focus of this study is to investigate the luminescence characteristics of FLICC under atmospheric to low-pressure environments. In the experiment, the pressure in the low-pressure chamber can be adjusted between 10 Pa and 0.1 MPa, and the chamber is filled with a 1% concentration of CH4/N2 mixture. A femtosecondlaser is incident into the low-pressure chamber and interacts with the mixed gas, inducing a chemical reaction to generate high-energy CN. Fluorescence is emitted through the transition of CN (B-X), and the spectrum is imaged using an ICCD camera and spectrometer. By capturing spectral information at different delays, the intensity and duration of various luminescence spectral lines of CN under different pressures are obtained, and a curve of spectral intensity versus pressure is established. The results show that as the pressure decreases, the luminescence intensity of CN gradually decreases. At the pressure of 10 Pa, it still maintains a good signal intensity. Through the delayed imaging of an ICCD camera, its fluorescence lifetime is about 5 μs, which meets the requirements of FLICC velocimetry technology. This research lays the foundation for the application of FLICC technology in low-pressure environments.
|
|
Received: 2024-11-18
Accepted: 2025-04-17
|
|
|
|
Corresponding Authors:
GAO Qiang
E-mail: qiang.gao@tju.edu.cn
|
|
[1] Koizumi H, Kawahara H, Yaginuma K, et al. Transactions of the Japan Society for Aeronautical and Space Sciences, Aerospace Technology Japan, 2016, 14(30): 13.
[2] Polk J, Kakuda R, Anderson J, et al. Validation of the NSTAR Ion Propulsion System on the Deep Space One Mission-Overview and Initial Results[C]. 35th Joint Propulsion Conference and Exhibit, 1999: 2274.
[3] Johnson L, Meyer M, Palaszewski B, et al. Acta Astronautica, 2013, 82(2): 148.
[4] Tummala A R, Dutta A. Aerospace, 2017, 4(4): 58.
[5] Krejci D, Lozano P. Proceedings of the IEEE, 2018, 106(3): 362.
[6] Frisbee R H. Journal of Propulsion and Power, 2003, 19(6): 1129.
[7] Lev D R, Herscovitz J, Zuckerman Z. Cold Gas Propulsion System Conceptual Design for the SAMSON Nanosatellite[C]. 50th AIAA/ASME/SAE/ASEE Joint Propulsion Conference, 2014: 3759.
[8] Ranjan R, Karthikeyan K, Riaz F, et al. Applied Energy, 2018, 220: 921.
[9] Estevadeordal J, Jiang N, Cutler A D, et al. Applied Physics B, 2018, 124: 41.
[10] YANG Wen-bin, CHEN Li, YAN Bo, et al(杨文斌,陈 力,闫 博,等). Journal of Experiments in Fluid Mechanics(实验流体力学), 2022, 36(4): 94.
[11] Estruch D, Lawson N J, Garry K P. Journal of Aerospace Engineering, 2009, 22(4): 383.
[12] Wang S, Si J, Shao J, et al. Optical Engineering, 2017, 56(11): 111705.
[13] Abdulwahab M R, Ali Y H, Habeeb F J, et al. Journal of Advanced Research in Fluid Mechanics and Thermal Sciences, 2020, 65(2): 213.
[14] Andrade A, Hoffman E N A, LaLonde E J, et al. Optics Express, 2022, 30(23): 42199.
[15] Vedula R, Mittal M, Schock H J. Journal of Fluids Engineering, 2013, 135(12): 121203.
[16] QI Xin-hua, CHEN Li, YAN Bo, et al(齐新华,陈 力,闫 博,等). Spectroscopy and Spectral Analysis (光谱学与光谱分析), 2021, 41(6): 1745.
[17] DeLuca N J, Miles R B, Kulatilaka W D, et al. Femtosecond Laser Electronic Excitation Tagging (FLEET) Fundamental Pulse Energy and Spectral Response[C]. 30th AIAA Aerodynamic Measurement Technology and Ground Testing Conference, 2014: 2227.
[18] Grady N, Pitz R W. Applied Optics, 2014, 53(31): 7182.
[19] Pitz R W, Wehrmeyer J A, Ribarov L A, et al. Measurement Science and Technology, 2000, 11(9): 1259.
[20] Leonov B S, Moran A N, North S W, et al. Optics Letters, 2024, 49(3): 426.
[21] Michael J B, Edwards M R, Dogariu A, et al. Applied Optics, 2011, 50(26): 5158.
[22] Danehy P M, Burns R A, Reese D T, et al. Annual Review of Fluid Mechanics, 2022, 54(1): 525.
[23] Gao Q, Zhang D, Li X, et al. Sensors and Actuators A: Physical, 2019, 287: 138.
[24] Zhang D, Li B, Gao Q, et al. Applied Spectroscopy, 2018, 72(12): 1807.
[25] Li B, Zhang D, Li X, et al. Journal of Physics D: Applied Physics, 2018, 51(29): 295102.
[26] Han L, Gao Q, Li B, et al. Optics and Lasers in Engineering, 2022, 155: 107060.
[27] Lin S, Zhang Y, Zhang H, et al. Physics of Plasmas, 2021, 28(7): 073302.
[28] Peters C J, Burns R A, Miles R B, et al. Measurement Science and Technology, 2021, 32(3): 035202.
[29] Jonsson M, Borggren J, Aldén M, et al. Applied Physics B, 2015, 120: 587.
[30] Kong F, Luo Q, Xu H, et al. The Journal of Chemical Physics, 2006, 125(13): 133320.
[31] LI Ming, GAO Qiang, CHEN Shuang, et al(李 明,高 强,陈 爽,等). Acta Photonica Sinica(光子学报), 2022, 51(3): 0314001.
[32] Théberge F, Liu W, Simard P T, et al. Physical Review E, 2006, 74(3): 036406.
[33] Couairon A, Franco M, Méchain G, et al. Optics Communications, 2006, 259(1): 265.
[34] Méchain G, Olivier T, Franco M, et al. Optics Communications, 2006, 261(2): 322.
[35] Xu H L, Azarm A, Bernhardt J, et al. Chemical Physics, 2009, 360(1-3): 171.
[36] Mitryukovskiy S, Liu Y, Ding P, et al. Optics Express, 2014, 22(11): 12750. |
| [1] |
JIAO Long1, LI Ying1, TONG Rong-chao2, WANG Cai-ling3. Identification of Sandstone Lithology Based on Hyperspectral Combined With Support Vector Machine Algorithm[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(09): 2496-2501. |
| [2] |
FAN Bing-rui1, 2, ZHAI Ai-ping1, WANG Dong1, LIANG Ting3, ZHANG Gen-wei2*, CAO Shu-ya2*. Research on the Recognition of Mixed Mid-Infrared Spectra of Hazardous Chemicals Based on an Improved High-Order Residual Network[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(09): 2459-2466. |
| [3] |
ZHANG Xin-zhi1, SAIMAITI Patiguli1, ZHANG Lu-wen1, YANG Ya-fei2*, BIAN Xi-hui1, 3*. Research Progress on Geographical Origin Discrimination of Traditional Chinese Medicines Based on Near-Infrared Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(09): 2410-2416. |
| [4] |
WANG Shi-qi, LIU Zi-rui, LI Qin-hao, ZHANG Xue-min*. Design of a Lightweight and Compact Self-Aligned PG Imaging
Spectrometer[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(09): 2614-2619. |
| [5] |
ZHU Shi-hao1, FENG Jie1*, LI Xin-ting1, SUN Li-cun1, LIU Jie2, YUAN Ping1, YANG Ren-xiang1, DENG Hong-yang1. Reconstruction of Chinese Paintings Based on Hyperspectral Image
Fusion Using Res-CAE Deep Learning[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(09): 2428-2436. |
| [6] |
ZHAO Min-jie1, SI Fu-qi1*, ZHOU Hai-jin1, JIANG Yu1, WANG Shi-mei1, ZHAN Kai1, YAN Ge2. Research on Spectral Simulation Method of Space-Borne Limb
Imaging Spectrometer[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(09): 2437-2444. |
| [7] |
ZHANG Xue-li1, 2, YANG Hao1, 2, LI Chen-fei1, 2, SUN Yi-le1, 2, LIU Zong-lin1, 2, ZHENG De-cong1, 2, SONG Hai-yan1, 2*. Origin Discrimination and Soluble Protein Content Prediction of Dried Daylily Based on Near Infrared Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(09): 2491-2495. |
| [8] |
XU Wei-xuan1, CHEN Wen-bin2*, SHAN Ai-xian3. Determination and Analysis of Rb/Sr Ratio in Yixing Purple Sand Using Energy Dispersive X-Ray Fluorescence Spectrometry[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(09): 2550-2556. |
| [9] |
SHI Guang-yuan1, WANG Yuan-bin1, 2, 3*, WANG Ying-hao1, SHAN Meng-jie1, DING Lei-yi1, CUI Min-chao1, 2, 3, LUO Ming1, 2, 3. Online Monitoring for Surface Integrity of γ-TiAl in Laser Shock Peening Based on Plasma Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(09): 2517-2525. |
| [10] |
FANG Jia-xuan, DONG Xi-wen, XU Zi-rui, QU Dong-ming, YANG Guang*, SUN Hui-hui*. A Waste Plastic Classification Method Based on Laser Spectral Fusion
Detection Technology[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(09): 2484-2490. |
| [11] |
HU Lin-zhen1, 3, 6, XIA Tian4, ZHANG Chao1, 2, 3*, YANG Ke-ming5, GAO Xue-zheng1, 3, LI Xiao-lei1, 3, WAN Ming-ming7. Exploration of Spectral Variation and Element Identification Under
Environmental Geological Data Simulation of Heavy Metal Pollution[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(09): 2658-2665. |
| [12] |
BU Zi-chuan, LIU Ji-hong*, REN Kai-li, LIU Chi, ZHANG Jia-geng, YAN Xue-wen. Raman Spectral Sample Data Enhancement Method Based on Voigt
Function[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(09): 2502-2510. |
| [13] |
FENG Hao-heng1, 2, 3, 4, LI Ke-qing5, 6, NIU Yuan-yuan2, 4, SUN Qing-di2, 4, XU Jin-chang2, 4, FANG Guang-you1, 2, 3, 4, CHEN Jian5, 6, HU Min7, 8, 9*, WANG Zhen-you1, 2, 3, 4*. Study on Identification Methods of Pericarpium Citri Reticulatae Based on Time-Gated Raman Spectroscopy and Support Vector Machine[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(09): 2557-2562. |
| [14] |
GUAN Zi-ran, HU Cong, SHI Qiao*, WU Hui-feng, HE Wen-feng. Study on Remote Analysis Method of Insulator Contamination Grades Based on Laser-Induced Breakdown Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(09): 2563-2568. |
| [15] |
CHENG Yu-hu, WU Shi-jia, WANG Hao-yu, WANG Xue-song*. Cross-Modal Dual-Channel Camouflaged Object Detection Method for Visible-Spectrum Image[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(09): 2632-2641. |
|
|
|
|
