[1] HOEGH-GULDBERG O, BRUNO J F. The impact of climate change on the world's marine ecosystems[J]. Science, 328, 1523-1528(2010).

[2] CODISPOTI L A. Interesting times for marine N₂O[J]. Science, 327, 1339-1340(2010).

[3] ZHUANG Q, MELILLO J M, MCGUIRE A D et al. Net emissions of CH₄ and CO₂ in Alaska： implications for the region's greenhouse gas budget[J]. Ecological Applications, 17, 203-212(2007).

[4] ROBERTS C M, O'LEARY B C, MCCAULEY D J et al. Marine reserves can mitigate and promote adaptation to climate change[J]. Proceedings of the National Academy of Sciences of the United States of America, 114, 6167-6175(2017).

[5] HELFTER C, MULLINGER N, VIENO M et al. Country-scale greenhouse gas budgets using shipborne measurements： a case study for the UK and Ireland[J]. Atmospheric Chemistry and Physics, 19, 3043-3063(2019).

[6] SCHNEISING O, BERGAMASCHI P, BOVENSMANN H et al. Atmospheric greenhouse gases retrieved from SCIAMACHY： comparison to ground-based FTS measurements and model results[J]. Atmospheric Chemistry and Physics, 12, 1527-1540(2012).

[7] WUNCH D, TOON G C, HEDELIUS J K et al. Quantifying the loss of processed natural gas within California’s South Coast Air Basin using long-term measurements of ethane and methane[J]. Atmospheric Chemistry and Physics, 16, 14091-14105(2016).

[8] NAKAGAWA H, AOKI S, SAGAWA H et al. IR heterodyne spectrometer MILAHI for continuous monitoring observatory of Martian and Venusian atmospheres at Mt. Haleakalā， Hawaii[J]. Planetary and Space Science, 126, 34-48(2016).

[9] KRABBE A, MEHLERT D, RÖSER H P et al. SOFIA， an airborne observatory for infrared astronomy[J]. European Journal of Physics, 34, S161-S177(2013).

[10] WILSON E L, DIGREGORIO A J, VILLANUEVA G et al. A portable miniaturized laser heterodyne radiometer （mini-LHR） for remote measurements of column CH（4） and CO₂[J]. Applied Physics B， Lasers and Optics, 125, 11(2019).

[11] HOFFMANN A, HUEBNER M, MACLEOD N et al. Spectrally resolved thermal emission of atmospheric gases measured by laser heterodyne spectrometry[J]. Optics Letters, 43, 3810-3813(2018).

[12] ROBINSON I, BUTCHER H L, MACLEOD N A et al. Hollow waveguide-miniaturized quantum cascade laser heterodyne spectro-radiometer[J]. Optics Express, 29, 2299-2308(2021).

[13] SHEN F J, HU X Y, LU J et al. Design of an all hollow fiber-coupled middle infrared laser heterodyne radiometer （LHR）[J]. Microwave and Optical Technology Letters, 65, 1324-1330(2023).

[14] LI J, XUE Z Y, LI Y et al. Real-time measurement of atmospheric CO₂， CH₄ and N₂O above rice fields based on laser heterodyne radiometers （LHR）[J]. Agronomy, 13, 373(2023).

[15] LI J, XUE Z Y et al. Erbium-doped fiber amplifier （EDFA）-assisted laser heterodyne radiometer （LHR） working in the shot-noise-dominated regime[J]. Optics Letters, 48, 5229(2023).

[16] WANG J J, TU T, ZHANG F et al. External-cavity diode laser-based near-infrared broadband laser heterodyne radiometer for remote sensing of atmospheric CO₂[J]. Optics Express, 31, 9251-9263(2023).

[17] SHEN F J, HU X Y, LU J et al. Performance characterization of a fully transportable mid-infrared laser heterodyne radiometer （LHR）[J]. Sensors, 23, 978(2023).

[18] DENG H, LI M X, HE Y B et al. Laser heterodyne spectroradiometer assisted by self-calibrated wavelength modulation spectroscopy for atmospheric CO₂ column absorption measurements[J]. Spectrochimica Acta Part A： Molecular and Biomolecular Spectroscopy, 230, 118071(2020).

[19] DENG H, YANG C G, XU Z Y et al. Development of a laser heterodyne spectroradiometer for high-resolution measurements of CO₂， CH（4）， H₂O and O（2） in the atmospheric column[J]. Optics Express, 29, 2003-2013(2021).

[20] DENG H, LI R S, LIU H et al. Optical amplification enables a huge sensitivity improvement to laser heterodyne radiometers for high-resolution measurements of atmospheric gases[J]. Optics Letters, 47, 4335-4338(2022).

[21] 李仁仕, 邓昊, 金谷雨. 本振激光强度调制激光外差光谱遥测技术研究[J]. 环境工程, 41, 9-13(2023).

     LI R S, DENG H, JIN G Y et al. Research on laser heterodyne spectrum telemetry technology based on local oscillator laser intensity modulation[J]. Environmental Engineering, 41, 9-13(2023).

[22] ZENEVICH S, GAZIZOV I S, SPIRIDONOV M V et al. IVOLGA： a high-resolution heterodyne near-infrared spectroradiometer for Doppler studies of Venus atmospheric dynamics[C], 52(2022).

[23] PARVITTE B, ZÉNINARI V, THIÉBEAUX C et al. Infrared laser heterodyne systems[J]. Spectrochimica Acta Part A： Molecular and Biomolecular Spectroscopy, 60, 1193-1213(2004).