Isotopic composition of oxygen in snow-and-firn thickness on the Eastern peak of Elbrus, the Caucasus

The isotopic composition of oxygen of the snow-and-firn and snow thickness on the Eastern peak of Elbrus had been studied. In 2006-2008, a number of snow samples were taken in the near-peak area of Elbrus to analyze the isotopic composition of them. The drilling was performed at the crater of the Eastern peak in 2006 (64 samples) while in 2017 the samples were taken from snow pit (25 samples). Another core to a depth of 23.8 m was extracted at the Western Plateau (118 samples) for the purpose to compare local 5¹⁸О values with samples from the Eastern peak. The δ¹⁸О values in the snow-and-firn thickness from the crater of the Eastern peak vary from -6.8 to -19.41 %o with the average value of -12.61 %o. It was revealed that snow layers with extremely low values of δ¹⁸О (down to -30 %) found on the eastern slope were absent on the western plateau. The loss of part of the annual isotope precipitation signal due to the winter extra light horizons could be caused by two reasons: wind drift of the freshly deposited snow, as well as the absence of part of the winter snowfalls with isotope-light precipitation at altitudes higher 5300 m. Seasonal variations of δ¹⁸О values, equal to 12 % and found in the snow-and-firn thickness on the Eastern peak, indicate that formation of the isotopic characteristics of snow is determined here by the equilibrium Rayleigh condensation and this is associated with the annual amplitude of the air temperature by a coefficient of 0.6 %o/°C. In the isotopic record obtained on the Western plateau of Elbrus, the relationship of values δ¹⁸О with the condensation temperature may be disturbed due to the frequent change of the main moisture-bearing air masses. This leads to significantly different δ¹⁸О values in precipitation at the same temperatures (the connection of seasonal δ¹⁸О values with the annual amplitude of air temperature varies from 0.3 to 1.12 %о/°С).

1. Dansgaard W. Stable isotopes in precipitation Tellus 1964, 16: 436-468

2. Mikhalenko V, Sokratov S., Kutuzov S., Ginot P, Legrand M, Preunkert S., Lavrentiev I., Kozachek A., Ekaykin A., Fain X., Lim S., Schotterer U., Lipenkov V., Toropov P Investigation of a deep ice core from the Elbrus western plateau, the Caucasus, Russia. The Cryosphere. 2015, 9: 2253-2270.

3. Kozachek A.V, Ekaykin A.A., Mikhalenko V.N., Lipenkov V. Ya., Kutuzov S.S. Izotopnyy sostav ledyanykh kernov, po-luchennykh na Zapadnomplato El'brusa. Isotopic composition of ice cores obtained in the Western Plateau of Elbrus . LediSneg. Ice and Snow. 2015, 55 (4): 35-49. [In Russian] .

4. Naftz D.L., Susong D.D., Cecil L.D., Schuster P.F. Variations Between 618O in Recently Deposited Snow and on-Site Air Temperature, Upper Fremont Glacier, Wyoming Earth Paleoenvironments: Records Preserved in Mid- and Low-Latitude Glaciers Developments in Paleoenvironmen-tal Research V 9 Eds : DeWayne Cecil L , Green J R , Thompson L. G. Springer, Dordrecht, 2004: 217-234.

5. Fisher D.A., Koerner R.M., Paterson W.S.B., Dansgaard W. , Gundestrup N., Reeh N. Effect of wind scouring on climatic records from ice-core oxygen-isotope profiles . Nature 1983, 301 (20): 205-209

6. Friedman I., Benson C., Gleason J. Isotopic changes during snow metamorphism . Stable Isotope Geochemistry: A Tribune to Samuel Epstein . The Geochemical Society, Special Publication. 1991, 3: 211-221.

7. Sommerfeld R.A., Friedman I., Nilles M. The Fractionation of Natural Isotopes During Temperature Gradient Metamorphism of Snow. Seasonal Snow covers: Physics, Chemistry, Hydrology Eds : H G Jones, W J Or-ville-Thomas . NATO ASI Series . 1987, 211: 95-105.

8. Sommerfeld R.A., Judy C., Friedman I. Isotopic changes during the formation of depth hoar in experimental snowpacks Stable isotope geochemistry: a tribute to Samuel Epstein . Eds . : H . P. Taylor, Jr, O’Neill J . R. , I . R. Kaplan . Washington, DC, Geochemical Society, 1991: 205-209. (Special Publication 3.)

9. Sturm M., Benson C.S.Vapor transport, grain growth and depth-hoar development in the subarctic snow .Journ .of Glaciology .1997, 43 (143): 42–59 .

10. 10 . Hachikubo A., Hashimoto S., Nakawo M., Nishimura K .Isotopic mass fractionation of snow due to depth hoar formation .Polar Meteorology .Glaciology .2000 .V .14 .P.1–7 .

11. Bolzan J.F, Pohjola V.A.Reconstruction of the undiffused seasonal oxygen isotope signal in central Greenland ice cores .Journ .of Geophys .Research .2000, 105 (C9): 22095–22106 .

12. Johnsen S.J, Clausen H.B., Cuffey K.M., Hoffmann G., Schwander J., Creyts T. Diffusion of stable isotopes in polar firn and ice: the isotope effect in firn diffusion . Physics of the Ice Core Records .Ed .By T .Hondoh . Hokkaido University Press, 2000: 121–140 .

13. Helsen M.M., Van de Wal R.S.W., Van den Broeke M.R., Van As D., Meijer H.A.J., Reijmer C.H. Oxy-gen isotope variability in snow from western Dronning Maud Land, Antarctica and its relation to temperature . Tellus .2005 .Ser .B .57 (5): 423–435 .

14. Vasil’chuk Yu.K., Chizhova Ju.N., Papesh V., Budantseva N.A. Vysotnyi izotopnyi effekt v snege na lednike Garabashi v Priel'brus'ye.High altitude isotope effect in the snow on the Garabashi glacier in the Elbrus region . Kriosfera Zemli.Earth's Cryosphere .2005, IX (4): 72–81 .[In Russian] .

15. Vasil’chuk Yu.K., Chizhova Ju.N. Vysotnyi gradient raspredeleniya δ18О i dD v atmosfernykh osadkakh i v snezhnom pokrove vysokogornykh rayonov.Altitude gradient of δ18О and δD distribution in atmospheric precipitation and in snow cover of high mountain areas . Kriosfera Zemli. Earth's Cryosphere .2010, XIV (1): 13–21 .[In Russian] .

16. Vasil'chuk Y., Chizhova J., Frolova N., Budantseva N., Kireeva M., Oleynikov A., Tokarev I., Rets E., Vasil'chuk A.The altitudinal isotope effect in snow on the Elbrus Mountain, Central Caucasus .Geography, Environment, Sustainability.2019. https://doi.org/10.24057/2071-9388-2018-22 .

17. Mikhalenko V.N., Kutuzov S.S., Lavrentyev I.I., Kunakhovich M.G., Thompson L.G. Issledovaniya zapadnogo lednikovogo plato El'brusa: rezul'taty i perspektivy.Studies of the western glacial plateau of Elbrus: results and prospects . Materialy Glyatsiologicheskikh Issledovaniy .Data of Glaciological Studies .2005, 99: 185–190 .[In Russian] .

18. Gat J.R., Carmi I.Evolution of the isotopic composition of atmospheric Waters in the Mediterranean Sea Area .Journ .of Geophys .Research .1970, 75: 3039–3048 .10.1029/JC075i015p03039 .

19. Pfahl S., Sodemann H.What controls deuterium excess in global precipitation? Climate of the Past .2014, 10: 771–781 .

20. Dee D.P., Uppalaa S.M., Simmons A.J., Berrisford P., Poli P., Kobayashi S., Andrae U., Balmaseda M.A., Balsamo G., Bauer P., Bechtold P., Beljaars A.C.M., van de Berg L., Bidlot J., Bormann N., Delsol C., Dragani R., Fuentes M., Geer A.J., Haimberger L., Healy S.B., Hersbach H., Holm E.V., Isaksen L., Kallberg P., Kohler M., Matricardi M., McNally A.P., Monge-Sanz B.M., Morcrette J.-J., Park B.-K., Peubey C., de Rosnay P., Tavolato C., Thepaut J.-N., Vitart F.The ERA-Interim reanalysis: Configuration and performance of the data assimilation system .Quarterly Journ .of the Royal Meteorological Society.2011, 137: 553–59721.

21. Rozanski K., Araguas-Araguas L., Gonfiantini R. Relation between long-term trends of oxygen-18 isotope composition of precipitation and climate Science 1992, 258: 981-985.

22. Toropov P.A., Mikhalenko V.N., Kutuzov S.S., Morozova P.A., Shestakova A.A. Temperaturnyi i radiatsionnyi rezhim lednikov na sklonakh El'brusa v period ablyat-sii za posledniye 65 let. Temperature and radiation regime of glaciers on slopes of the Mount Elbrus in the ablation period over last 65 years . Led i Sneg. Ice and Snow. 2016, 56 (1): 5-19. [In Russian],

23. Johnsen S.J., Dansgaard W, White J.W. The origin of Arctic precipitation under present and glacial condition . Tellus . 1989, 41: 452-469.

24. Jouzel J., Alley R.B., Cuffey K.M., Dansgaard W., Grootes P., Hoffmann G., Johnsen S.J., Koster R.D., Peel D., Shuman C.A., Stievenard M., Stuiver M., White J. Validity of the temperature reconstruction from water isotopes in ice cores Journ of Geophys Research 1997, 102 (C12): 26471-26487.

25. Bohleber P., Wagenbach D., Schoner W. To what extent do water isotope records from low accumulation Alpine ice cores reproduce instrumental temperature series? Tellus B. 2013, 65: 20148 .

26. Sturm C., Zhang Q., Noone D. An introduction to stable water isotopes in climate models: benefits of forward proxy modelling for paleoclimatology Climate of the Past. 2010, 6: 115-129.

27. Fisher D., Osterberg E, Dyke A., Dahl-Jensen D. The Mt Logan Holocene late Wisconsinan isotope record: tropical Pacific-Yukon connections . Holocene. 2008, 18: 667-677.

28. Tashilova A., Ashabokov B., Kesheva L., Teunova N. Analysis of Climate Change in the Caucasus Region: End of the 20th-Beginning of the 21st Century Climate . 2019, 7 (11) . doi: 0.3390/cli7010011.

29. Jean-Baptiste P., Jouzel J., Stievenard M., Ciais P. Experimental determination of the diffusion rate of deu-terated water vapor in ice and application to the stable isotopes smoothing of ice cores Earth and Planetary Science Letters . 1998, 158: 81-90.

30. Van der Wel L.G., Gkinis V., Pohjola V.A., Meijer H.A.J. Snow isotope diffusion rates measured in a laboratory experiment . Journ. of Glaciology. 2011, 57 (201): 330-338.