[1] CRUZ-URIBE A M, CRAIG G, GARBER J M et al. Single spot Rb-Sr isochron dating of biotite by LA-MC-ICP-MS/MS[J]. Geostandards and Geoanalytical Research, 47, 795-809(2023).

[2] IMAYAMA T, UEDA H, USUKI T et al. Variability of protoliths and pressure-temperature conditions of amphibolites from the Ohmachi Seamount （Izu-Bonin-Mariana arc）： evidence of a fossil subduction channel in a modern intra-oceanic arc[J]. Mineralogy and Petrology, 114, 305-318(2020).

[3] BARANDOVSKI L, ŠAJN R, BAČEVA ANDONOVSKA K et al. Modeling of the ambient radiation dose level by using passive moss biomonitoring in Macedonia[J]. Journal of Radioanalytical and Nuclear Chemistry, 330, 267-278(2021).

[4] MIMOUNI M, BULSEI J, DARLINGTON M et al. Cost-effectiveness of 82-Rubidium PET myocardial perfusion imaging for the diagnosis of myocardial ischemia depending on the prevalence of coronary artery disease[J]. EJNMMI Research, 13, 9(2023).

[5] BOLLINGER C, ETOUBLEAU J. Precise determination of rubidium in geological reference materials by ID-TIMS and WD-XRF： a discussion for the basalt BIR-1[J]. Geostandards Newsletter, 25, 277-282(2001).

[6] NIE N X, DAUPHAS N, HOPP T et al. Chromatography purification of Rb for accurate isotopic analysis by MC-ICPMS： a comparison between AMP-PAN， cation-exchange， and Sr resins[J]. Journal of Analytical Atomic Spectrometry, 36, 2588-2602(2021).

[7] QI X Q. Theoretical Study on Hyperfine Splittings and Isotope Shifts of Light Helium-like Ions[D](2021).

     戚晓秋. 类氦轻离子的超精细劈裂和同位素位移理论研究[D](2021).

[8] HUANG J, HUANG Y B, LU X J et al. Measurements of atmospheric water vapor by a 1.316 μm optical fiber laser heterodyne radiometer[J]. Frontiers in Physics, 10, 835189(2022).

[9] CHOI S U, HAN S C, YUN J I. In situ detection of neodymium isotopes using tunable diode laser absorption spectroscopy for nuclear forensic analysis[J]. Journal of Analytical Atomic Spectrometry, 38, 166-173(2023).

[10] LI J, FAN B B, ZENG Q J et al. Research on open circuit detection method of hydrogen sulfide/methane based on 8.309 μm QCL[J]. Opt. Precision Eng., 32, 467-477(2024).

     李俊, 范斌斌, 曾庆杰. 基于8.309 μm QCL的硫化氢/甲烷开路式检测方法研究[J]. 光学 精密工程, 32, 467-477(2024).

[11] BARTLETT J H, CASTRO A. Isotopic spectroscopy of uranium atomic beams produced by thermal reduction of uranium compounds[J]. Spectrochimica Acta Part B： Atomic Spectroscopy, 155, 61-66(2019).

[12] YANG T Y, GONG T, GUO G Q et al. Design and achievement of a device for high-precision ammonia gas detection based on laser spectroscopy[J]. Chinese Optics, 16, 1129-1136(2023).

     杨天悦, 宫廷, 郭古青. 氨气高精度激光光谱检测装置的设计及实现[J]. 中国光学（中英文）, 16, 1129-1136(2023).

[13] YANG SH H, QIAO SH D, LIN D Y et al. Research on highly sensitive detection of oxygen concentrations based on tunable diode laser absorption spectroscopy[J]. Chinese Optics, 16, 151-157(2023).

     杨舒涵, 乔顺达, 林殿阳. 基于可调谐半导体激光吸收光谱的氧气浓度高灵敏度检测研究[J]. 中国光学（中英文）, 16, 151-157(2023).

[14] 李龙, 师帅, 宫廷. 燃煤锅炉高温腐蚀气体激光在线监测设备研究[J]. 中国光学（中英文）, 17, 1060-1067(2024).

     LI L, SHI SH, GONG T et al. Research on laser online monitoring equipment for high-temperature corrosive gas in coal-fired boilers[J]. Chinese Optics, 17, 1060-1067(2024).

[15] BERGEVIN J, WU T H, YEAK J et al. Dual-comb spectroscopy of laser-induced plasmas[J]. Nature Communications, 9, 1273(2018).

[16] WEI W, CASTRO A. Sensitive detection of an erbium isotope in an atomic beam using cavity ring-down spectroscopy[J]. Applied Spectroscopy, 78, 120-124(2024).

[17] QI G, HUANG Y B, HUANG J et al. Highly sensitive spectral measurement of rubidium isotopes using open multi-pass cell in tunable diode laser absorption spectroscopy[J]. Journal of Analytical Atomic Spectrometry, 39, 935-941(2024).

[18] XIN F X, LI J, GUO J J et al. Measurement of atmospheric CO₂ column concentrations based on open-path TDLAS[J]. Sensors, 21, 1722(2021).

[19] HUANG X D, HAO X J, PAN B W et al. Flame imaging technology based on 64-pixel area array sensor[J]. Micromachines, 15, 44(2024).

[20] LU SH Y, MA L H, ZHANG J P et al. Temperature measurement in methane-ammonia co-fired laminar premixed flame using mid-infrared laser absorption tomography[J]. Opt. Precision Eng., 32, 2733-2743(2024).

     陆盛曜, 马柳昊, 张健鹏. 中红外层析吸收光谱技术应用于甲烷掺氨层流预混火焰温度测量[J]. 光学 精密工程, 32, 2733-2743(2024).

[21] DU Y J, PENG Z M, DING Y J. Wavelength modulation spectroscopy for recovering absolute absorbance[J]. Optics Express, 26, 9263-9272(2018).

[22] PENG Z M, DU Y J, DING Y J. Highly sensitive， calibration-free WM-DAS method for recovering absorbance-part I： theoretical analysis[J]. Sensors, 20, 681(2020).

[23] STECK D A. Rubidium 85 D Line Data[EB/OL](2023).

[24] STECK D A. Rubidium 87 D Line Data[EB/OL](2023).

[25] MIYABE M, JUNG K et al. Laser ablation absorption spectroscopy for isotopic analysis of plutonium： Spectroscopic properties and analytical performance[J]. Spectrochimica Acta Part B： Atomic Spectroscopy, 134, 42-51(2017).