Analysis of the wind waves height and the duration of ice-free period along the Northern Sea Route from 1979 to 2021

   The study deals with the analysis of wind waves in the Arctic seas of Russia along the Northern Sea Route. Data on wind wave parameters were obtained on the basis of the WAVEWATCH III spectral model, and data on wind and sea ice concentration for the period from 1979 to 2021 – from the NCEP/CFSR/CFSv2 reanalysis. Estimates of the distribution of the average, maximum and 95th percentile height of significant waves and the duration of ice-free period along two variants of the route along the Northern Sea Route (NSR) have been obtained with a space resolution of ~20 km. Trends of the parameters under consideration were also estimated for 43 years. The minimum duration of ice-free period is about 30 days on the northern route of the NSR in the East Siberian Sea. The minimum duration on the southern route is never less than 65 days. The average annual wave height during the ice-free period exceeds 2 m in the Barents Sea, 1,6 m in the Chukchi Sea and is no more than 1,2 m for the rest of the route. The maximum wave height and the 95th percentile of wave height are significantly lower on the southern route. The trends for the duration of the ice-free period are positive all along the NSR, and amount to 15–20 days per 10 years. The maximum trend values of 52 days per 10 years are observed north of the Novaya Zemlya Archipelago. The minimum values of trends for the ice-free period are observed in the area of the Vilkitsky Strait and in the northeastern part of the Kara Sea. The maximum trend for wave height during the ice-free period is observed in the eastern part of the East Siberian Sea reaching 0,33 m in 10 years on the northern and 0,12 m in 10 years on the southern route of the NSR.

1. Alekseev G.V., Radionov V.F., Aleksandrov E.I. et al. Izmenenija klimata Arktiki pri global’nom poteplenii [Arctic climate change under global warming], Problemy Arktiki i Antarktiki, 2015, no. 1(103), p. 33–41. (In Russian)

2. Cabral I.S., Young I.R., Toffoli A. Long-Term and Seasonal Variability of Wind and Wave Extremes in the Arctic Ocean, Front. Mar. Sci, 2022, vol. 9, p. 80, DOI: 10.3389/fmars.2022.802022.

3. Chiroşcă A.-M., Rusu L. Characteristics of the Wind and Wave Climate along the European Seas Focusing on the Main Maritime Routes, J. Mar. Sci. Eng., 2022, 10.

4. Gurlev I.V., Makosko A.A., Malygin I.G. Analiz sostojanija i razvitija transportnoj sistemy Severnogo morskogo puti [Analysis of the state and development of the transport system of the Northern Sea Route], Arktika: jekologija i jekonomika, 2022, t. 12, no. 2(46), p. 258–270. doi: 10.25283/2223-4594-2022-2-258-270. (In Russian)

5. Ivanov V. Arctic Sea Ice Loss Enhances the Oceanic Contribution to Climate Change, Atmosphere, 2023, 14, 409, DOI: 10.3390/atmos14020409.

6. Khon V.C., Mokhov I.I., Semenov V.A. Transit Navigation through Northern Sea Route from Satellite Data and CMIP5 Simulations, Environ. Res. Lett, 2017, vol. 12, 024010.

7. Kibanova O.V., Hon V.Ch., Mohov I.I., Eliseev A.V. Izmenenija prodolzhitel’nosti navigacionnogo perioda Severnogo morskogo puti v XXI veke po raschetam s ansamblem klimatiche-skih modelej: bajesovskie ocenki [Climate model-based changes of the navigation period duration at the north sea route in the 21^st century: bayesian estimates], Doklady Akademii nauk, 2018, t. 481, vol. 1, p. 89–94. (In Russian)

8. Li J., Ma Y., Liu Q., Zhang W., Guan C. Growth of wave height with re-treating ice cover in the Arctic, Cold Reg. Sci. Technol, 2019, vol. 164, p. 102790, DOI: 10.1016/j.coldregions.2019.102790.

9. Mohov I.I., Hon V.Ch. Prodolzhitel’nost’ navigacionnogo perioda i ee izmenenija dlja Severnogo morskogo puti: model’nye ocenki [The duration of the navigation period and changes for the northern sea route: model estimates], Arktika: jekologija i jekonomika, 2015, vol. 2(18), p. 88–95. (In Russian)

10. Mohov I.I., Hon V.Ch., Prokof’eva M.A. New model estimates of changes in the duration of the navigation period for the northern sea route in the 21^st century, Doklady Earth Sciences, 2016, vol. 468, no. 2, p. 641–645.

11. Mohov I.I., Pogarskij F.A. Variations in the characteristics of sea waves in the arctic basin caused by climate changes in the 21^st century based on model simulations, Doklady Earth Sciences, 2021, vol. 496, no. 2, p. 164–167. doi: 10.31857/S2686739721020134.

12. Myslenkov S.A. Modelirovanie vetrovogo volnenija v more Laptevyh, Vostochno-Sibirskom i Chukotskom morjah [Modeling of the wind waves in the Laptev, East Siberian and Chukchi seas], Gidrometeorologicheskie issledovanija i prognozy, 2023, no. 1(387), p. 87–101. doi: 10.37162/2618-9631-2023-1-87-101. (In Russian)

13. Myslenkov S., Platonov V., Kislov K. et al. Thirty-Nine-Year Wave Hindcast, Storm Activity, and Probability Analysis of Storm Waves in the Kara Sea, Russia, Water, 2021, 13(5), 648, DOI: 10.3390/w13050648.

14. Myslenkov S., Samsonov T., Shurygina A. et al. Wind waves web atlas of the Russian seas, Water, 15, 11(2023), 2036.

15. Myslenkov S., Kruglova E., Medvedeva A. et al. Number of storms in several Russian seas: Trends and connection to large-scale atmospheric indices, Russian Journal of Earth Sciences, 2023, vol. 23, no. 3, p. ES3002.

16. Nesterov E.S. Vetrovoe volnenie v Arkticheskih morjah (obzor) [Wind waves in the arctic seas (review)], Gidrometeorologicheskie issledovanija i prognozy, 2020, no. 3(377), p. 19–41. (In Russian)

17. Ogorodov S.A., Shabanova N.N., Kessel’ A.S. et al. Izmenenie gidrometeorologicheskogo potenciala termoabrazii beregov morej rossijskoj Arktiki [Changes of hydrometeorological potential of thermoabrasion on the russian arctic coasts], Vestn. Mosk. Un-ta, Ser. 5, Geogr., 2022, no. 1, p. 26–42. (In Russian)

18. Osipova E.Je., Smirnov S.V., Hairova T.A. Predposylki razvitija jeksporta rossijskoj Arktiki, kabotazhnyh perevozok i proektnyh gruzov dlja arkticheskih proektov [Preconditions for the development of russian arctic export, coastal (cabotage) transportation and project cargo for the arctic demand], Arktika i Sever, 2019, no. 37, p. 5–21. URL: https://www.arcticandnorth.ru/article_index_years.php?ELEMENT_ID=341224 (In Russian)

19. Plotnikov V.V., Vrazhkin A.N., Mezenceva L.I. et al. Izmenchivost’ gidrometeorologicheskogo rezhima morej vostochnogo sektora Arktiki (Vostochno-Cibirskoe, Chukotskoe) v sovremennyj period [Variability of Hydrometeorological regime of seas of east Arctic sector (east Siberian, Chukchi) in the modern period], Izvestija Tomskogo politehnicheskogo universiteta, Inzhiniring georesursov, 2020, vol. 331, no. 7, p. 103–115. (In Russian)

20. Rules for the development and conduct of maritime operations ND no. 2-090601-010. Russian Maritime Register of Shipping. St. Petersburg, 2022, 142 p. (In Russian)

21. Rostov I.D., Rostova E.V., Voroncov A.A. Tendencii klimaticheskih izmenenij termicheskih uslovij morja Laptevyh za poslednie 37 let [Tendencies of climatic changes for thermal condition of the laptev sea in the last 37 years], Vestnik Dal’nevostochnogo otdelenija Rossijskoj akademii nauk, 2019, no. 1, p. 97–107. (In Russian)

22. Shabanov P.A. Changes in the ice-free period duration in the Kara sea coastal zone from satellite data, Oceanology, 2022, vol. 62, no. 4, p. 447–457.

23. Shalina E.V. Izmenenie ledovitosti Severnyh morej Rossii i ocenka dostupnosti Severnogo morskogo puti po dannym sputnikovogo monitoringa [Ice Retreat in the Seas of the Russian Arctic and Increased Availability of the Northern Sea Route from Satellite Passive Microwave Observations], Issledovanie Zemli iz kosmosa, 2015, no. 4, p. 67. doi: 10.7868/S0205961415040090. (In Russian)

24. Sharmar V.M. Markina Evaluation of interdecadal trends in sea ice, surface winds and ocean waves in the Arctic in 1980–2019, Russian Journal of Earth Sciences, 2021, 21(2), 1–11, DOI: 10.2205/2020ES000741.

25. Soomere T., Eelsalu M. On the wave energy potential along the eastern Baltic Sea coast, Reewable Energy, 2014, 71, 221–233.

26. Tojmenceva I.A., Fedorenko R.V. Perspektivy razvitija transportno-logisticheskoj infrastruktury Severnogo Morskogo puti v ramkah programmy “odin pojas, odin put’” [Prospects for the development of the transport and logistics infrastructure of the northern sea route within the framework of the program “one belt, one road”], Vestn. Volzhskogo un-ta im. V.N. Tatishheva, 2023, vol. 2, no. 1(51), p. 140–149. doi: 10.51965/2076-7919_2023_2_1_140. (In Russian)

27. Tret’jakov V.Ju., Frolov S.V., Sarafanov M.I. Izmenenija ledovyh uslovij plavanija po marshrutu Obskaja guba – Beringov proliv za 1998–2018 gody, Fundamental’naja i prikladnaja gidrofizika, 2019, vol. 12, no. 3, p. 65–75. (In Russian)

28. Tolman H. The WAVEWATCH III Development Group User Manual and System Documentation of WAVEWATCH III Version 6.07, Tech. Note 333, March 2019, NOAA/NWS/NCEP/MMAB 2019.

29. Voronina S.A., Porfir’ev B. N., Semikashev V.V. et al. Posledstvija izmenenij klimata dlja jekonomicheskogo rosta i razvitija otdel’nyh sektorov jekonomiki rossijskoj Arktiki [Climate change impact on economic growth and specific sectors’ development of the Russian Arctic], Arktika: jekologija i jekonomika, 2017, no. 4(28), p. 4–17. doi: 10.25283/2223-4594-2017-4-4-17. (In Russian)

30. Vrazhkin A.N. Rezhim volnenija morej vostochnoj Arktiki v nachale XXI stoletija [The Eastern Arctic seas wave climate in the beginning of the 21^st century], Trudy DVNIGMI, 2017, vyp. 155, p. 164–177. (In Russian)

31. Waseda T., Webb A., Sato K. et al. Correlated increase of high ocean waves and winds in the ice-free waters of the Arctic Ocean, Sci. Reports, 2018, vol. 8, no. 4489.

32. Zelenkov M.Ju. Transportno-logisticheskaja sistema Severnogo morskogo puti: perspektivy, problemy i puti ih reshenija [Transport and logistics system of the northern sea route: prospects, problems and solutions], Arktika: jekologija i jekonomika, 2019, no. 4(36), p. 131–140. doi: 10.25283/2223-4594-2019-4-131-140 (In Russian)