Vol. 36, issue 09, article # 5
Copy the reference to clipboard
Abstract:
Changes in the base height of the lower layer cloudiness and cumulonimbus clouds over the territory of Western Siberia are analyzed based on laser data for the period 2010–2021. We established that, in general, there is a decrease in the base height of lower clouds and its increase for cumulonimbus clouds. An increase in the base height of lower cloudiness occurs from north to south. More meridional distribution is obtained for cumulonimbus clouds. The seasonal course of the lower cloudiness and cumulonimbus clouds base height in the south of the territory has a maximum in summer. Two maxima are observed in the center and in the north: for lower cloudiness in summer and spring and for cumulonimbus clouds in winter and summer. The results of the cluster analysis show a significant difference in the base height for cumulonimbus clouds (in comparison with lower cloudiness) at different stations, which is presumably due to differences in earth’s surface characteristics and station height above sea level, as well as regional features of atmospheric circulation and convective processes
Keywords:
cloud base height, lower cloudiness, cumulonimbus clouds, laser sounding data, Western Siberia
References:
. IPCC, 2021: Summary for Policymakers // Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change / V. Masson-Delmotte, P. Zhai, A. Pirani, S.L. Connors, C. Péan, S. Berger, N. Caud, Y. Chen, L. Goldfarb, M.I. Gomis, M. Huang, K. Leitzell, E. Lonnoy, J.B.R. Matthews, T.K. Maycock, T. Waterfield, O. Yeleki, R. Yu, B. Zhou (eds.). Cambridge University Press, 2023. 2391 р. DOI: 10.1017/9781009157896.
2. Mokhov I.I. Izmeneniya klimata: prichiny, riski, posledstviya, problemy adaptatsii i regulirovaniya // Vestn. RAN. 2022. V. 92, N 1. P. 3–14.
3. Chen B., Liu Z. Global water vapor variability and trend from the latest 36-year (1979 to 2014) data of ECMWF and NCEP reanalyses, radiosonde, GPS, and microwave satellite // J. Geophys. Res.: Atmos. 2016. V. 121. P. 11442–11462.
4. Chernokul'skiy A.V., Yeliseyev A.V., Kozlov F.A., Korshunova N.N., Kurganskii M.V., Mokhov I.I., Semenov V.A., Shvets N.V., Shikhov A.N., Yary¬nich Yu.I. Opasnyye atmosfernyye yavleniya konvektiv¬nogo kharaktera v Rossii: nablyudayemyye izmeneniya po razlichnym dannym // Meteorol. i gidrol. 2022. N 5. P. 27–41.
5. Tretiy otsenochnyy doklad ob izmeneniyakh klimata i ikh posledstviyakh na territorii Rossiyskoy Federatsii. Obshcheye rezyume. SPb.: Naukoyemkiye tekhnologii, 2022. 124 p.
6. Komarov V.S., Matvienko G.G., Il'in S.N., Lomakina N.Ya. Otsenka lokal'nykh osobennostey dolgovremennogo izmeneniya oblachnogo pokrova nad territoriyey Sibiri s ispol'zovaniyem rezul'tatov yeye klimaticheskogo rayonirovaniya po rezhimu obshchey i nizhney oblachnosti // Optika atmosf. i okeana. 2015. V. 28, N 1. P. 59–65.
7. Chernokulsky A.V., Esau I., Bulygina O.N., Davy R. Climatology and interannual variability of cloudiness in the Atlantic Arctic from surface observations since the late Nineteenth Century // J. Clim. 2017. V. 30, N 6. P. 2103–2120.
8. Bezrukova A.N., Chernokul'skii A.V. Rossiyskiye issledovaniya oblakov i osadkov v 2015–2018 gg. // Izv. RAN. Fiz. atmosf. i okeana. 2020. V. 56, N 4. P. 397–417.
9. Shakina N.P., Skriptunova Ye.N. Rezhim nizkoy oblachnosti i prognoz vysoty yeye nizhney granitsy na aerodromakh aziatskoy territorii Rossii // Gidro¬meteorologicheskiye issledovaniya i prognozy. 2019. N 2. P. 59–75.
10. Rukovodstvo po meteorologicheskim pribo¬ram i metodam nablyudeniy. Zheneva: VMO, 2014. 1389 p.
11. Doc 8896. Rukovodstvo po aviatsionnoy meteorologii. Monreal': ICAE, 2009. 177 p.
12. Skorokhodov A.V., Kur'yanovich K.V. Ispol'zovaniye dannykh CALIOP dlya otsenki vysoty nizhney granitsy oblakov na sputnikovykh snimkakh MODIS // Sovremennyye problemy distantsionnogo zondirovaniya Zemli iz kosmosa. 2022. V. 19, N 2. P. 43–56.
13. Komarov V.S., Il'in S.N., Lavrinenko A.V., Loma¬kina N.Ya., Gorev Ye.V., Nakhtigalova D.P. Klimati¬cheskiy rezhim nizhney oblachnosti nad territoriyey Sibiri i yego sovremennyye izmeneniya. Chast' 1. Osobennosti rezhima nizhney oblachnosti // Optika atmosf. i okeana. 2013. V. 26, N 7. P. 579–583.
14. Komarov V.S., Matviyenko G.G., Lomakina N.Ya., Il'in S.N., Lavrinenko A.V. Statisticheskaya struk¬tura i dolgovremennyye izmeneniya nizhney sloistoob¬raznoy oblachnosti nad regionom Sibiri kak osnova dlya meteorologicheskoy podderzhki resheniya priklad¬nykh zadach. Chast' 1. Statistika nizhney sloistoobraz¬noy oblachnosti // Optika atmosf. i okeana. 2015. V. 28, N 7. P. 622–629.
15. Vetrova Ye.I., Skriptunova Ye.N., Shakina N.P. Rezhim nizkoy oblachnosti i yeye prognoz na aerodromakh yevropeyskoy territorii byvshego SSSR // Meteo¬rol. i gidrol. 2013. N 1. P. 12–31.
16. Chernokul'skii A.V. Analiz global'nogo polya oblach¬nosti i svyazannykh s yego variatsiyami klimaticheskikh effektov. Dis. ... kand. fiz.-mat. nauk. M., 2010. 179 p.
17. Kharyutkina Ye.V., Loginov S.V., Moraru Ye.I., Pus¬tovalov K.N., Martynova Yu.V. Dinamika kharakte¬ristik ekstremal'nosti klimata i tendentsii opasnykh meteorologicheskikh yavleniy na territorii Zapadnoy Sibiri // Optika atmosf. i okeana. 2022. V. 35, N 2. P. 136–142.
18. Iowa State University. Iowa Environmental Mesonet. ASOS-AWOS-METAR Data Download URL: https://mesonet.agron.iastate.edu/request/download.phtml (last access: 20.02.2023).
19. Oblakomer CL31. Rukovodstvo pol'zovatelya. Vaisala, 2005. 131 p.
20. Petin A.N., Vasil'yev P.V. Geoinformatika v ratsional'nom nedropol'zovanii. Belgorod: BelGU, 2011. 268 p.
21. Golitsyn G.S., Rutkevich B.P., Rutkevich P.B. Nizh¬nyaya granitsa oblachnosti // Sovremennyye problemy distantsionnogo zondirovaniya Zemli iz kosmosa. 2006. V. 1, N 3. P. 263–269.
22. Badakhova G.Kh., Volkova V.I., Shevchenko A.I. Prostranstvenno-vremennoye raspredeleniye oblachnosti v Stavropol'skom kraye v sovremennykh klimaticheskikh usloviyakh // Nauka i obrazovaniye segodnya. 2020. N 6. Ch. 1. P. 97–101.
23. Khromov S.P., Mamontova L.I. Meteorologicheskiy slovar'. L.: Gidrometeoizdat, 1974. 568 p.
24. Kononova N.K. Izmeneniya global'noy tsirkulyatsii atmosfery v period 1899–2018 gg. // Fundamen¬t. i prikl. klimatol. 2019. N 4. P. 120–138.
