Long-Term Variability of the Timing of Freezing and the Duration of Ice Phenomena in the White Sea Based on Satellite and in Situ Observations for 1980–2020

The long-term variability of the ice regime of the White Sea for the period 1980–2020 was studied. The reliability of the satellite data used was also assessed by comparing them with in situ observation data. We use the regular hydrometeorological monitoring data from eight marine observation points, as well as satellite microwave passive sounding data (NSIDC) with a spatial resolution of 25 km and a time step of 1–2 days to form series of the main elements of the sea ice regime (the characteristic dates of ice regime and duration of ice phenomena). The average statistical dates of the start freezing and the ice breakup for the entire water area of the White Sea and its regions were obtained. Regression analysis of the data showed that the start freezing and the ice breakup dates have shifted towards the winter months over the past 40 years. The shifts occurred at average rates of 7.4 days/10 years and 4.7 days/10 years, respectively, according to in situ observations, and 11.9 days/10 years and 4.1 days/10 years, respectively, according to satellite observations. Overall, over the past 40 years, the average duration of ice phenomena in the White Sea has decreased by 47 days according to in situ observations and by 62 days according to satellite observations. Comparative analysis of satellite and in situ data showed significant differences in the average values of absolute deviations (up to 70 days) in determining the characteristic dates of the White Sea ice regime; however, the time series of characteristic dates are in good agreement with each other (pair correlation coefficients of 0.76/0.82 between the time series of dates of start freezing and dates of ice break up). This proves the possibility of using satellite data to calculate the regime indicators of ice phenomena over a long period in order to identify patterns in the development of ice processes, assess their climatic trends and develop methods for forecasting ice conditions.

characteristic dates, ice regime, White Sea, situ data , satellite data,

1. Baklagin V.N. Multiyear variability of ice concentration in the White Sea according to satellite data. Led i Sneg. Ice and Snow. 2022, 62 (4): 579–590. https://doi.org/10.31857/S2076673422040153 [In Russian].

2. Gidrometeorologiya i gidrohimiya morej SSSR. Hydrometeorology and hydrochemistry of the seas of the USSR. V. 2. No. 1. Leningrad: GidrometeoIzdat, 1991: 241 p. [In Russian].

3. Dumanskaya I.O. Analysis of the variability of the position of drifting ice edges and the maximum ice coverage of the White Sea. Trudy Gidrometcentra Rossii. Proc. of the Hydrometeorological Center of Russia. 2004, 339: 45–54 [In Russian].

4. Dumanskaya I.O. Ledovye usloviya morej evropejskoj chasti Rossii. Ice conditions of the seas of the European part of Russia. Obninsk: IG–SOCIN, 2014: 608 p. [In Russian].

5. Zabolotskih E.V. Review of methods to retrieve sea ice parameters from satellite microwave radiometer data. Izvestiya RAN. Fizika atmosfery i okeana. Proc. of the RAS. Physics of the atmosphere and ocean. 2019, 55 (1): 128–151. https://doi.org/10.31857/S0002-3515551128-151 [In Russian].

6. Johannessen O.M., Aleksandrov V.Yu., Frolov I.E., Sandven S., Pettersson L.H., Bobylev L.P., Kloster K., Smirnov V.G., Mironov E.U., Babich N.G. Nauchnye issledovaniya v Arktike. T. 3. Distancionnoe zondirovanie morskih l’dov na severnom morskom puti: izuchenie i primenenie. Scientific research in the Arctic. V. 3. Remote sensing of sea ice on the Northern Sea route: study and application. St. Petersburg: Nauka, 2007: 512 p. [In Russian].

7. Smirnov V.G. (Ed). Sputnikovye metody opredeleniya harakteristik ledyanogo pokrova morej. Satellite methods for determining the characteristics of the sea ice cover. St. Petersburg: Arctic and Antarctic Research Institute, 2011: 240 p. [In Russian].

8. Nastavlenie gidrometeorologicheskim stanciyam i postam RD 52.10.842-2017. Vypusk 9. Gidrometeorologicheskie nablyudeniya na morskih stanciyah i postah. Chast’i. Gidrologicheskie nablyudeniya na beregovyh stanciyah i postah. Instructions for hydrometeorological stations and posts RD 52.10.842-2017. Issue 9. Hydrometeorological observations at sea stations and posts. Part 1. Hydrological observations at coastal stations and posts. Moscow: OOO “Izdatel’stvo ITRK”, 2017: 385 p. [In Russian].

9. Shalina E.V. Reduction of the Arctic ice cover according to satellite passive microwave sensing. Sovremennye problemy distancionnogo zondirovaniya Zemli iz kosmosa. Current problems in remote sensing of the Earth from space. 2013, 10 (1): 328–336 [In Russian].

10. Shalina E.V. Johannessen O.M., Bobylev L.P. Changes in the Arctic ice cover according to satellite passive microwave sensing data from 1978 to 2007. Sovremennye problemy distancionnogo zondirovaniya Zemli iz kosmosa. Current problems in remote sensing of the Earth from space. 2008, 2 (5): 228–223 [In Russian].

11. Alekseeva T.A., Frolov S.V. Comparative analysis of satellite and shipborne data on ice cover in the Russian Arctic seas. Izvestiya, Atmospheric and Oceanic Physics. 2013, 49: 879–885. https://doi.org/10.1134/S000143381309017X

12. Alekseeva T., Tikhonov V., Frolov S., Repina I., Raev M., Sokolova J., Sharkov E., Afanasieva E., Serovetnikov S. Comparison of Arctic Sea Ice Concentrations from the NASA Team, ASI, and VASIA2 Algorithms with Summer and Winter Ship Data. Remote Sensing. 2019, 11: 2481. https://doi.org/10.3390/rs11212481

13. Cavalieri D.J., Parkinson C.L. Arctic sea ice variability and trends, 1979–2010. The Cryosphere 2012, 6: 881–889. https://doi.org/10.5194/tc-6-881-2012

14. Cavalieri D., Parkinson C., DiGirolamo N., Ivanov A. Intersensor calibration between F13 SSM/I and F17 SSMIS for global sea ice data records. IEEE Geoscience and Remote Sensing Letters. 2011, 9 (2): 233–236. https://doi.org/10.1109/LGRS. 2011.2166754

15. Cavalieri D., Parkinson C., Gloersen P., Comiso J., Zwally H.J. Deriving Long-term Time Series of Sea Ice Cover from Satellite Passive-microwave Multisensor Data Sets. J. Geophys. Res. 1999, 104 (C7): 1580315814.

16. Comiso J.C., Parkinson C.L., Gersten R., Stock L. Accelerated decline in the Arctic sea ice cover. Geophys. Res. Letters. 2007, 34: L01703. https://doi.org/10.1029/2007/GL031972

17. Filatov N.N., Pozdnyakov D.V., Johannessen O.M., Pettersson L.H. White Sea: Its Marine Environment and Ecosystem Dynamics Influenced by Global Change. Berlin; Heidelberg: Springer, 2005: 463 p. https://doi.org/10.1007/3-540-27695-5

18. Kern S., Lavergne T., Notz D., Pedersen L.T., Tonboe R. Satellite passive microwave sea-ice concentration data set inter-comparison for Arctic summer conditions. The Cryosphere. 2020, 14: 2469–2493. https://doi.org/10.5194/tc-14-2469-2020

19. Kern S., Lavergne T., Notz D., Pedersen L.T., Tonboe R.T., Saldo R., Sørensen A.M. Satellite passive microwave sea-ice concentration data set intercomparison: closed ice and ship-based observations. The Cryosphere. 2019, 13: 3261–3307. https://doi.org/10.5194/tc-13-3261-2019

20. Knuth M.A., Ackley S.F. Summer and early-fall Sea-ice concentration in the Ross Sea: Comparison of in Situ ASPeCt observations and satellite passive microwave estimates. Annals of Glaciology. 2006, 44: 303–309. https://doi.org/10.3189/172756406781811466

21. Laliberté F., Howell S.E.L., Kushner P.J. Regional variability of a projected sea ice-free Arctic during the summer months // Geophys. Res. Letters. 2016, 43: 256–263. https://doi.org/10.1002/2015GL066855

22. Maslanik J., Stroeve J., Fowler C., Emery W. Distribution and trends in Arctic sea ice age through spring 2011. Geophys. Research Letters. 2011, 38 (13): L13502. https://doi.org/10.1029/2011GL047735

23. Smith L.C., Stephenson S.R. New Trans-Arctic shipping routes navigable by midcentury. Proc. Natl. Acad. Sci. U.S.A. 2013, 110 (13): E1191–E1195. https://doi.org/10.1073/pnas.121421211

24. Meier W.N. Comparison of passive microwave ice concentration algorithm retrievals with AVHRR imagery, in Arctic peripheral seas. IEEE Transactions on Geoscience and Remote Sensing. 2005, 43: 1324–1337. https://doi.org/10.1109/TGRS. 2005.846151

25. Meier W.N., Khalsa S.J.S., Savoie M.H. Intersensor calibration between F-13 SSM/I and F-17 SSMIS near-realtime Sea Ice estimates // IEEE Transactions on Geoscience and Remote Sensing. 2011, 49 (9): 3343–3349. https://doi.org/10.1109/TGRS. 2011.2117433 NSIDC: official site: Electronic data. Retrieved from: https://nsidc.org/data/g02135/versions/3 (Last access: May 8, 2025).

26. Pang X., Pu J., Zhao X., Ji Q., Qu M., Cheng Z. Comparison between AMSR2 Sea Ice Concentration Products and Pseudo-Ship Observations of the Arctic and Antarctic Sea Ice Edge on Cloud-Free Days. Remote Sensing. 2018, 10: 317. https://doi.org/10.3390/rs10020317

27. Spreen G., Kaleschke L., Heygster G. Sea ice remote sensing using AMSR-E 89-GHz channels. J. Geophys. Res. Oceans. 2008, 113: C02S03. https://doi.org/10.1029/2005JC003384

28. Stroeve J., Notz D. Changing state of Arctic sea ice across all seasons. Environmental Research Letters. 2018, 13 (10): 103001. https://doi.org/10.1088/1748-9326/aade56

29. Tikhonov V.V., Raev M.D., Sharkov E.A., Boyarskii D.A., Repina I.A., Komarova N.Y. Satellite microwave radiometry of sea ice of Polar Regions: A review. Izvestiya, Atmospheric and Oceanic Physics. 2016, 52: 1012–1030. https://doi.org/10.1134/S0001433816090267

30. Tonboe R.T., Eastwood S., Lavergne T., Sørensen A.M., Rathmann N., Dybkjær G., Pedersen L.T., Høyer J.L., Kern S. The EUMETSAT sea ice concentration climate data record. The Cryosphere. 2016, 10: 2275–2290. https://doi.org/10.15770/EUM_SAF_OSI_0013

31. Tschudi M.A., Meier W.N., Stewart J.S. An enhancement to sea ice motion and age products at the National Snow and Ice Data Center (NSIDC). The Cryosphere. 2020, 14: 1519–1536. https://doi.org/10.5194/tc-14-1519-2020