UDC 535.8
CSCSTI 29.31
Russian Classification of Professions by Education 03.03.02
Russian Library and Bibliographic Classification 223
Russian Trade and Bibliographic Classification 613
BISAK SCI053000 Physics / Optics & Light
The results of a numerical study are presented to assess the possibilities of remote measurement of carbon dioxide content in the atmosphere. A conclusion is made about the possibility of measuring background concentrations of carbon dioxide in various environmental conditions - from the tropics to the Arctic latitudes. The most preserved ranges of carbon dioxide sensing are ~1572.8–1572.6 nm and 1573.5–1573.2 nm.
remote sensing, atmosphere, carbon dioxide
1. Davydov D.K., Belan B.D., Antohin P.N., Antohina O.Yu., Antonovich V.V., Arshinova V.G., Arshinov M.Yu., Ahlestin A.Yu., Belan S.B., Dudorova N.V., Ivlev G.A., Kozlov A.V., Pestunov D.A., Rasskazchikova T.M., Savkin D.E., Simonenkov D.V., Sklyadneva T.K., Tolmachev G.N., Fazliev A.Z., Fofonov A.V. Monitoring atmosfernyh parametrov: 25 let TOR-stancii IOA SO RAN // Optika atmosfery i okeana. 2018. T. 31. № 10. S. 845-853.
2. Antohin P.N., Arshinova V.G., Arshinov M.Yu., Aryasov V.E., Belan B.D., Belan S.B., Davydov D.K., Ivlev G.A., Kozlov A.V., Panov A.V., Prokushkin A.S., Putilin I.R., Rasskazchikova T.M., Savkin D.E., Simonenkov D.V., Tolmachev G.N., Fofonov A.V. Sravnenie potokov parnikovyh gazov, izmerennyh s pomosch'yu kompleksov nauchnogo oborudovaniya samoleta-laboratorii Yak-40 i observatorii «ZOTTO» // Optika atmosfery i okeana. 2024. T. 37. № 12. S. 1028–1034.
3. Siozos P., Psyllakis G., Samartzis P.C., Velegrakis M. Autonomous Differential Absorption Laser Device for Remote Sensing of Atmospheric Greenhouse Gases // Remote Sens. 2022. V. 14. № 3. P. 460.
4. Antohina O.Yu., Bobrovnikov S.M., Zharkov V.I., Zorkal'ceva O.S., Trifonov D.A. Osobennosti vertikal'nogo raspredeleniya temperatury nad g. Tomskom vo vremya vnezapnogo stratosfernogo potepleniya zimoy 2023 g. po dannym Sibirskoy lidarnoy stancii // Optika atmosfery i okeana. 2024. T. 37. № 11. S. 947–953.
5. Siozos P., Psyllakis G., Velegrakis M. Remote Operation of an Open-Path, Laser-Based Instrument for Atmospheric CO2 and CH4 Monitoring // Photonics. 2023. V. 10. №. 4. P. 386.
6. Lu H., Zheng C., Zhang L., Liu Z., Song F., Li X., Zhang Y., Wang Y. A Remote Sensor System Based on TDLAS Technique for Ammonia Leakage Monitoring // Sensors. 2021. V. 21. №. 7. P. 2448.
7. Mariage V., Pelon J., Blouzon F., Victori S., Geyskens N., Amarouche N., Drezen C., Guillot A., Calzas M., Garracio M., Wegmuller N., Sennéchael N., Provost C. IAOOS microlidar-on-buoy development and first atmospheric observations obtained during 2014 and 2015 arctic drifts // Opt. Express. 2017. V. 25. №. 4. P. 73–84.
8. Gordon I.E. et al. The HITRAN2020 molecular spectroscopic database // J. Quant. Spectrosc. Radiat. Transf. 2022. V. 277. P. 107949.
9. Krekov G.M., Rahimov R.F. Optiko-lokacionnaya model' kontinental'nogo aerozolya. Novosibirsk: Nauka, 1982. 199 s.
10. Penndorf R. Tables of the Refractive Index for Standard Air and the Rayleigh Scattering Coefficient for the Spectral Region between 0.2 and 20 μm and Their Application to Atmospheric Optics // J. Opt. Soc. Am. 1957. V. 47, № 2. P. 176.
