Relationship between structure and chemical composition of fast sea and lake ice in the Cape Marre-Sale area, Western Yamal

The texture, structure, ionic and trace element composition of samples of fast (coastal-sea) and lake ice collected in 2014 in the area of Cape Marre-Sale (the North-Western Siberia) were analyzed. The following main types of the ice structure were identified in ice sections: firn ice with randomly oriented small crystals; lake large- and small-crystalline bubble ice; layered fast sea ice with small isometric and vertically elongated crystals. The upper part of the lake ice is formed by recrystallized snow containing marine aerosols and lake water. The coefficient of involvement of the main ions from the solution during the ice formation varies for lake ice from 0.02 to 1.51, for sea ice – from 0.10 to 0.23, and for coastal-marine - from 0.03 to 0.04. The difference in the degree of ion involvement into the lake ice is related to the sources of components entering the process of formation of firn and large ice crystals from lake water. Coastal sea ice has high concentrations of trace elements relative to the clarks of sea waters. The income of trace elements into the coastal sea ice is probably determined by continental runoff. It is established that the mineralization of seasonal ice increases with a decrease in the size of crystals. The dependence of the values of the Europium anomaly on the rate of ice formation was revealed. The Europium anomaly in coastal sea ice is inherited from seawater, and the upper part of lake ice is inherited from precipitation.

1. Kanevskij M.Z., Streleckaja I.D., Vasil'ev A.A. Regularities of the cryogenic structure formation of the Quaternary deposits of the Western Yamal (on the example of the Marre – Sale region) Kriosfera Zemli. Earth’s Cryosphere 2005, IX (3): 16–27 [In Russian]

2. Kritsuk L.N. Podzemnye ldy Zapadnoj Sibiri. Ground ice of West Siberia Moscow: Nauchnyy Mir, 2010: 352 p [In Russian]

3. Slagoda E.A., Mel'Nikov V.P., Opokina O.L. Reinjected ice stocks in sediments of the western Yamal peninsula. Doklady Akademii Nauk Reports of the Academy of Sciences 2010, 432 (1): 663–665

4. Shpolyanskaya N.A. Pleistotsen­golotsenovaya istoriya razvitiya kriolitozony Rossiyskoy Arktiki glazami podzemnykh l’dov. Pleistocene-Holocene history of permafrost development of Russian Arctic by eyes of underground ice Moscow–Izhevsk: Institute of Computer Studies, 2015: 343 p [In Russian]

5. French H.M, Harry, D.G. Observations on buried glacier ice and massive segregated ice, western Arctic coast, Canada Permafrost and Periglacial Processes 1990, 1: 31–43

6. French H.M., Harry D.G. Nature and origin of ground ice, Sandhills Moraine, southwest Banks Island, western Canadian Arctic Journ of Quaternary Science 1988, 3: 19–30

7. Pollard W.H The nature and origin of ground ice in the Herschel Island area, Yukon Territory Proceedings of the Fifth Canadian Permafrost Conference, Québec, 1990: 23–30

8. Murton J.B Ground-ice stratigraphy and formation at North Head, Tuktoyaktuk Coastlands, western Arctic Canada: a product of glacier-permafrost interactions Permafrost and Periglacial Processes 2005, 16: 31–50

9. Shumsky P.A. Osnovy strukturnogo ledovedeniya. Fundamentals of ice structure sciences Moscow: USSR Academy of Sciences, 1955: 492 p [In Russian]

10. Savelev B.A. Rukovodstvo po izucheniyu svoystv lda. Guide to the study of ice characteristic Moscow: Moscow State University, 1963: 198 p [In Russian]

11. Golubev V.N. Dependence of Ice Structure on Freezing Water Salinity II Mezhdunarodnaja konferencija po merzlotovedeniju. Proc of the 2nd Intern Conf on Cryolithology V 4 Yakutsk: Knizhnoe izd-vo, 1973: 180–184 [In Russian]

12. Tyshko K.P., Cherepanov N.V., Fedotov V.I. Kristallicheskoe stroenie morskogo ledjanogo pokrova. Crystal structure of sea ice cover St Petersburg: Gidrometeoizdat, 2000: 66 p [In Russian]

13. Ivlev L.S., Dovgalyuk Yu.A. Fizika atmosfernyh ajerozol'nyh sistemPhysics of atmospheric aerosol systems Physics of atmospheric aerosol systems St Petersburg: NIIKH SPbGU, 1999: 194 p [In Russian]

14. Zelinskaya E.V., Voronina E.Yu. Teoreticheskie aspekty ispolzovanija gidromineralnogo syrja. Theoretical Aspects of Using Hydromineral Raw Materials Moscow: Akad Estestvoznaniya, 2009: 118 p [In Russian]

15. Sabylina A.V., Efremova T.A. The chemical composition of ice and water under ice of Lake Onega (the case of Petrozavodsk Bay) Led i Sneg. Ice and Snow 2018, 58 (3): 417–428 [In Russian] https://doi.org/10.15356/2076-6734-2018-1-417-428

16. Kizyakov A.I., Streletskaya I.D., Savenko A.V., Kraynyukova I.A., Tokarev I.V. Chemical, isotopic and gas composition of the first-year sea ice in 2013–2015 from the data of cores taken at the BARNEO drifting stations Led i Sneg. Ice and Snow 2019, 59 (3): 363–376 [In Russian] doi: 10.15356/2076-6734-2019-3-387

17. Ivanov A.V. Kriogennaja metamorfizacija himicheskogo sostava prirodnyh ldov, zamerzajushhih i talyh vod. Cryogenic metamorphization of the chemical composition of natural ice, freezing and melt waters Khabarovsk: Dalnauka, 1998: 164 p [In Russian]

18. Anisimova N.P. Metody gidrogeohimii v merzlotovedenii. Methods of hydrogeochemistry in permafrost Yakutsk: Publishing House of the Permafrost Institute SB RAS, 2004: 78 p [In Russian]

19. Tikhonravova Y.V., Rogov V.V., Slagoda E.A. Genetic identification of ground ice by petrographic method Geography, environment, sustainability 2021, 14 (4): 20–32 https://doi.org/10.24057/2071-9388-2021-063

20. Solovov A.P., Arkhipov A.Ya., Bugrov V.A., Vorob’ov S.A., Gershman D.M., Grigoryan S.V., Kiyatovsky E.M., Matveev A.A., Milyaev S.A., Nikolaev. V.A., Perelman A.I., Shvarov Yu.V., Yufa B.Ya., Yaroshevsky A.A. Spravochnik po geohimicheskim poiskam poleznyh iskopaemyh. Reference book on geochemical prospecting of mineral resources Moscow: Nedra, 1990: 335 p [In Russian]

21. Gromet L.P., Dymek R.F., Haskin L.A., Korotev R.L. The «North American shale composite»: Its compilation, major and trace element characteristics Geochimica et Cosmochimica Acta 1984, 48 (12): 2469–2482

22. Kato Y., Ohta I., Tsunematsu T., Watanabe Y., Isozaki Y., Maruyama S., Imai N Rare earth element variations in Mid–Archean banded iron formations: implications for the chemistry of ocean and continent and plate tectonics Geochimica et Cosmochimica Acta 1998, 62: 3475–3497

23. Dubinin A.V. Geochemistry of rare earth elements in the ocean Lithology and Mineral Resources 2004, 39 (4): 289–307

24. Savelev B.A. Stroenie I sostav prirodnyh vod. The structure and composition of natural water Moscow: MGU, 1980: 280 p [In Russian]

25. Rogov V. V. Osnovy kriogeneza. Fundamentals of Cryogenesis Novosibirsk: GEO, 2009: 203 p [In Russian]

26. Butakov V.I, Slagoda E.A., Tikhonravova Ya.V., Opokina O.L., Tomberg I.V., Zhuchenko N.A. Hydrochemical composition and rare-earth elements in ice wedge of the Kara region cryolitozone key areas Izvestija Tomskogo politehnicheskogo universiteta. Inzhiniring georesursov. Bulletin of the Tomsk Polytechnic University Geo Аssets.Engineering 2020, 331 (2): 78–91 doi: 10.18799/24131830/2020/2/2483 [In Russian]

27. Ershov E.D., Chuvilin E.M., Smirnova O.G. Mobility of ions of chemical elements in ice and frozen rocks Doklady Akademii Nauk. Reports of the Academy of Sciences 1999, 367 (6): 796–798 [In Russian]

28. Petrich C., Eicken H. Growth, Structure and Properties of Sea Ice Oxford: Blackwell Publishing 2010 P 23–78

29. Butakov V.I., Slagoda E.A., Opokina O.L., Tomberg I.V., Zhuchenko N.A. The formation features of the hydrochemical and trace element composition of various types of ground ice at Marre-Sale Cape Earth՛s Cryosphere 2020, XXIV (5): 29–44 http://www.izdatgeo.ru/pdf/earth_cryo/2020-5/23_eng.pdf doi: 10.21782/EC2541-9994-2020-5(23-37).