空间外差拉曼光谱仪的光栅多级衍射杂散光分析与抑制方法
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摘要
光栅的多级衍射杂散光对空间外差拉曼光谱仪的成像质量具有重要影响。为了提高其成像质量,使光谱特征更准确,针对空间外差拉曼光谱仪中光栅产生的多级衍射杂散光进行分析与抑制研究。依据光学传递理论,利用ASAP软件对空间外差拉曼光谱仪中光栅产生的多级衍射杂散光进行仿真与分析,利用挡板、光阑和光学陷阱等方法设计了能够抑制-2.5°~2.5°视场范围内杂散光的结构。结果表明:光栅产生的多级衍射杂散辐射比由4.996×10~(-3)降到了1.57×10~(-8),设计的结构对空间拉曼光谱仪系统内因光栅产生的多级衍射杂散光具有良好的抑制效果,有效提高了系统的成像质量。
Stray light resulting from grating multistage diffraction influences the imaging quality of the spatial heterodyne Raman spectrometer(SHRS). In this study, the stray light was analyzed and controlled to enhance the precision of the SHRS. The optical transmission theory was employed to study the stray light produced by grating multistage diffraction in the SHRS using the ASAP software; a stray light controlling structure was designed in-2.5°-2.5° field-of-view via baffling, beam stopping, and light trapping. The results indicate that the stray light ratio of multistage diffraction is reduced from 4.996×10~(-3) to 1.57×10~(-8). Thus, the developed structure can efficiently control the stray light from grating multistage diffraction and improve the imaging quality of the SHRS.
Stray light resulting from grating multistage diffraction influences the imaging quality of the spatial heterodyne Raman spectrometer(SHRS). In this study, the stray light was analyzed and controlled to enhance the precision of the SHRS. The optical transmission theory was employed to study the stray light produced by grating multistage diffraction in the SHRS using the ASAP software; a stray light controlling structure was designed in-2.5°-2.5° field-of-view via baffling, beam stopping, and light trapping. The results indicate that the stray light ratio of multistage diffraction is reduced from 4.996×10~(-3) to 1.57×10~(-8). Thus, the developed structure can efficiently control the stray light from grating multistage diffraction and improve the imaging quality of the SHRS.
引文
[1] Todd Nathaniel.Spatial heterodyne Raman spectroscopy[D].Guildford:University of Surrey,2011:21- 27.
[2] Du J M.The enhancement mechanism of surface-enhanced Raman scattering applied in food security[D].Chengdu:Southwest Jiaotong University,2017.杜俊梅.应用于食品安全的表面增强拉曼的机理研究[D].成都:西南交通大学,2017.
[3] Li C,Feng Z C,Cao N.Development of deep ultraviolet laser Raman spectrometer[J].Bulletin of the Chinese Academy of Sciences,2011,26(5):589-592.李灿,冯兆池,曹凝.深紫外激光拉曼光谱仪研制[J].中国科学院院刊,2011,26(5):589-592.
[4] Overton G.Planetary and deep-space applications push spectroscopy to the outer limits[J].Laser Focus World,2012,48(7):36-45.
[5] Michael Angel S,Gomer N R,Sharma S K,et al.Remote Raman spectroscopy for planetary exploration:a review[J].Applied Spectroscopy,2012,66(2):137-150.
[6] Todd Nathaniel,Craig Underwood.A compact spatial heterodyne remote Raman spectrometer for Mars exploration[C]//62nd International Astronautical Congress,October 2011,Cape Town,South Africa.France:IAF,2011:1261-1271.
[7] Lamsal N,Michael Angel S.Deep-ultraviolet Raman measurements using a spatial heterodyne Raman spectrometer (SHRS)[J].Applied Spectroscopy.2015,69(5):525-534.
[8] Egan M J,Angel S M,Sharma S K.Standoff spatial heterodyne Raman spectrometer for mineralogical analysis[J].Journal of Raman Spectroscopy,2017,48(11):1613-1617.
[9] Ye S,Fang Y H,Hong J,et al.System design of spatial heterodyne spectrometer[J].Optics and Precision Engineering,2006,14(6):959-964.叶松,方勇华,洪津,等.空间外差光谱仪系统设计[J].光学精密工程,2006,14(6):959-964.
[10] Hu G X,Xiong W,Luo H Y,et al.The research of spatial heterodyne Raman spectroscopy with standoff detection[J].Spectroscopy and Spectral Analysis,2016,36(12):3951-3957.胡广骁,熊伟,罗海燕,等.用于远程探测的空间外差拉曼光谱技术研究[J].光谱学与光谱分析,2016,36(12):3951-3957.
[11] Luo H Y,Fang X J,Hu G X,et al.Hyper-resolution spatial heterodyne spectrometer for hydroxyl radical OH[J].Acta Optica Sinica,2018,38(6):0630003.罗海燕,方雪静,胡广骁,等.中高层大气OH自由基超分辨空间外差光谱仪[J].光学学报,2018,38(6):0630003.
[12] Qiu J,Qi X D,Li X T,et al.Development of a spatial heterodyne Raman spectrometer with echelle-mirror structure[J].Optics Express,2018,26(9):11994-12006.
[13] Yang J,Yin L,Yao X F,et al.Optical design and stray light suppression of a new portable echelle spectrometer[J].Acta Optica Sinica,2015,35(8):0812001.杨晋,尹禄,姚雪峰,等.新型便携式中阶梯光栅光谱仪光学设计与消杂散光研究[J].光学学报,2015,35(8):0812001.
[14] Luo H Y,Xiong W,Shi H L,et al.Study for signal-to-noise ratio of spatial heterodyne spectrometer[J].Acta Optica Sinica,2017,37(6):0612001.罗海燕,熊伟,施海亮,等.空间外差干涉光谱仪信噪比研究[J].光学学报,2017,37(6):0612001.
[15] Zhu Y.Study on the suppression of stray radiation in space optical system[D].Changchun:University of Chinese Academy of Sciences,2016:12-14.朱杨.空间光学系统杂散辐射抑制研究[D].长春:中国科学院大学,2016:12-14.
[2] Du J M.The enhancement mechanism of surface-enhanced Raman scattering applied in food security[D].Chengdu:Southwest Jiaotong University,2017.杜俊梅.应用于食品安全的表面增强拉曼的机理研究[D].成都:西南交通大学,2017.
[3] Li C,Feng Z C,Cao N.Development of deep ultraviolet laser Raman spectrometer[J].Bulletin of the Chinese Academy of Sciences,2011,26(5):589-592.李灿,冯兆池,曹凝.深紫外激光拉曼光谱仪研制[J].中国科学院院刊,2011,26(5):589-592.
[4] Overton G.Planetary and deep-space applications push spectroscopy to the outer limits[J].Laser Focus World,2012,48(7):36-45.
[5] Michael Angel S,Gomer N R,Sharma S K,et al.Remote Raman spectroscopy for planetary exploration:a review[J].Applied Spectroscopy,2012,66(2):137-150.
[6] Todd Nathaniel,Craig Underwood.A compact spatial heterodyne remote Raman spectrometer for Mars exploration[C]//62nd International Astronautical Congress,October 2011,Cape Town,South Africa.France:IAF,2011:1261-1271.
[7] Lamsal N,Michael Angel S.Deep-ultraviolet Raman measurements using a spatial heterodyne Raman spectrometer (SHRS)[J].Applied Spectroscopy.2015,69(5):525-534.
[8] Egan M J,Angel S M,Sharma S K.Standoff spatial heterodyne Raman spectrometer for mineralogical analysis[J].Journal of Raman Spectroscopy,2017,48(11):1613-1617.
[9] Ye S,Fang Y H,Hong J,et al.System design of spatial heterodyne spectrometer[J].Optics and Precision Engineering,2006,14(6):959-964.叶松,方勇华,洪津,等.空间外差光谱仪系统设计[J].光学精密工程,2006,14(6):959-964.
[10] Hu G X,Xiong W,Luo H Y,et al.The research of spatial heterodyne Raman spectroscopy with standoff detection[J].Spectroscopy and Spectral Analysis,2016,36(12):3951-3957.胡广骁,熊伟,罗海燕,等.用于远程探测的空间外差拉曼光谱技术研究[J].光谱学与光谱分析,2016,36(12):3951-3957.
[11] Luo H Y,Fang X J,Hu G X,et al.Hyper-resolution spatial heterodyne spectrometer for hydroxyl radical OH[J].Acta Optica Sinica,2018,38(6):0630003.罗海燕,方雪静,胡广骁,等.中高层大气OH自由基超分辨空间外差光谱仪[J].光学学报,2018,38(6):0630003.
[12] Qiu J,Qi X D,Li X T,et al.Development of a spatial heterodyne Raman spectrometer with echelle-mirror structure[J].Optics Express,2018,26(9):11994-12006.
[13] Yang J,Yin L,Yao X F,et al.Optical design and stray light suppression of a new portable echelle spectrometer[J].Acta Optica Sinica,2015,35(8):0812001.杨晋,尹禄,姚雪峰,等.新型便携式中阶梯光栅光谱仪光学设计与消杂散光研究[J].光学学报,2015,35(8):0812001.
[14] Luo H Y,Xiong W,Shi H L,et al.Study for signal-to-noise ratio of spatial heterodyne spectrometer[J].Acta Optica Sinica,2017,37(6):0612001.罗海燕,熊伟,施海亮,等.空间外差干涉光谱仪信噪比研究[J].光学学报,2017,37(6):0612001.
[15] Zhu Y.Study on the suppression of stray radiation in space optical system[D].Changchun:University of Chinese Academy of Sciences,2016:12-14.朱杨.空间光学系统杂散辐射抑制研究[D].长春:中国科学院大学,2016:12-14.
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