[1] A MAITY, S MAITHANI, M PRADHAN. Cavity ring-down spectroscopy： recent technological advancements， techniques， and applications. Analytical Chemistry, 93, 388-416(2021).

[2] [2] 2杜星湖， 薛颖， 何星， 等. 基于耦合光腔衰荡技术的高反射率测量［J］. 中国激光， 2020， 47（6）： 0604006. doi: 10.3788/CJL202047.0604006DUX H， XUEY， HEX， et al. High reflectivity measurement based on coupled cavity ring-down technique［J］. Chinese Journal of Lasers， 2020， 47（6）： 0604006.（in Chinese）. doi: 10.3788/CJL202047.0604006

[3] J THIÉBAUD, C FITTSCHEN. Near infrared cw-CRDS coupled to laser photolysis： Spectroscopy and kinetics of the HO₂ radical. Applied Physics B, 85, 383-389(2006).

[4] Y CHEN, K K LEHMANN, J KESSLER et al. Measurement of the ¹³C/¹²C of atmospheric CH₄ using near-infrared （NIR） cavity ring-down spectroscopy. Analytical Chemistry, 85, 11250-11257(2013).

[5] J MORVILLE, S KASSI, M CHENEVIER et al. Fast， low-noise， mode-by-mode， cavity-enhanced absorption spectroscopy by diode-laser self-locking. Applied Physics B, 80, 1027-1038(2005).

[6] G W TRUONG, K O DOUGLASS, S E MAXWELL et al. Frequency-agile， rapid scanning spectroscopy. Nature Photonics, 7, 532-534(2013).

[7] T P HUA, Y R SUN, J WANG et al. Frequency metrology of molecules in the near-infrared by NICE-OHMS. Optics Express, 27, 6106-6115(2019).

[8] E D BLACK. An introduction to Pound–Drever–Hall laser frequency stabilization. American Journal of Physics, 69, 79-87(2001).

[9] [9] 9李明星， 陈兵， 阮俊， 等. 近海大尺度区域二氧化碳的激光在线探测技术［J］. 光学 精密工程， 2020， 28（7）： 1424-1432. doi: 10.37188/OPE.20202807.1424LIM X， CHENB， RUANJ， et al. On-line detection of carbon dioxide in large scale offshore by laser technology［J］. Opt. Precision Eng.， 2020， 28（7）： 1424-1432.（in Chinese）. doi: 10.37188/OPE.20202807.1424

[10] [10] 10聂伟， 许振宇， 阚瑞峰， 等. 可调谐二极管激光吸收光谱技术测量低温流场水汽露点温度［J］. 光学 精密工程， 2018， 26（8）： 1862-1869. doi: 10.3788/OPE.20182608.1862NIEW， XUZ Y， KANR F， et al. Measurement of low water vapor dew-point temperature based on tunable diode laser absorption spectroscopy［J］. Opt. Precision Eng.， 2018， 26（8）： 1862-1869.（in Chinese）. doi: 10.3788/OPE.20182608.1862

[11] [11] 11袁峰， 高晶， 姚路， 等. 球载CRDS高灵敏度甲烷测量系统的研制［J］. 光学 精密工程， 2020， 28（9）： 1881-1892. doi: 10.37188/OPE.20202809.1881YUANF， GAOJ， YAOL， et al. Development of highly sensitive balloon-borne methane measurement system based on cavity ringdown spectroscopy［J］. Opt. Precision Eng.， 2020， 28（9）： 1881-1892.（in Chinese）. doi: 10.37188/OPE.20202809.1881

[12] J B DUDEK, P B TARSA, A VELASQUEZ et al. Trace moisture detection using continuous-wave cavity ring-down spectroscopy. Analytical Chemistry, 75, 4599-4605(2003).

[13] Y B HE. Ringdown and cavity-enhanced absorption spectroscopy using a continuous-wave tunable diode laser and a rapidly swept optical cavity. Chemical Physics Letters, 319, 131-137(2000).

[14] G GIUSFREDI, S BARTALINI, S BORRI et al. Saturated-absorption cavity ring-down spectroscopy. Physical Review Letters, 104, 110801(2010).

[15] [15] 15李想. 海水关键溶解气体高灵敏激光原位分析方法研究［D］. 合肥： 中国科学技术大学， 2020.LIX. Dissolved Gases Measurements in Seawater Using High Sensitivity Laser Spectrometer Technology［D］. Hefei： University of Science and Technology of China， 2020. （in Chinese）

[16] M NICKERSON. A review of Pound-Drever-Hall laser frequency locking. JILA， University of Colorado and NIST(2019).

[17] M BAHOURA, A CLAIRON. Ultimate linewidth reduction of a semiconductor laser frequency-stabilized to a Fabry-Perot interferometer. IEEE Transactions on Ultrasonics， Ferroelectrics， and Frequency Control, 50, 1414-1421(2003).

[18] J SU, M X JIAO, F JIANG. Pound-Drever-Hall laser frequency locking technique based on orthogonal demodulation. Optik, 168, 348-354(2018).

[19] L S ROTHMAN, D JACQUEMART, A BARBE et al. The HITRAN 2004 molecular spectroscopic database. Journal of Quantitative Spectroscopy and Radiative Transfer, 96, 139-204(2005).

[20] M SIMECKOVA, D JACQUEMART, L S ROTHMAN et al. Einstein A-coefficients and statistical weights for molecular absorption transitions in the HITRAN database. Journal of Quantitative Spectroscopy and Radiative Transfer, 98, 130-55(2006).