Dendrochronological analysis of conifers in avalanche catchments of the Northwestern Altai (Korgon River basin)

The purpose of the study was to date the powerful snow avalanches occurred in the avalanche catchment area in the river Korgon basin (Northwestern Altai) by the dendrochronological method. The paper presents the results of the analysis of a number of dendrochronological indicators of avalanches: the age of trees, the relation between widths of annual rings from opposite sides of the trunk, the presence of reactive (compressional) wood and traumatic resin canals, the dates of death and formation of wounds in trees, the presence of clearing effects (a sharp increase in growth) in three avalanche catchments, as well as a complex dendrochronological index of the avalanche activity. The dates of releases of the powerful avalanches were established down to 1570. It has been found that against the background of increasing amount of winter precipitation in these catchments, there are different trends in occurrence of the avalanches, which is determined by their morphological properties. In the avalanche areas with steeper slopes, due to repeated unloading of the avalanche centers in winter, the probability of releasing of powerful avalanches decreases. For the same reason, the powerful avalanches do not release during the years of maximum snow accumulation. The trends in the avalanche activity in the region under consideration had been obtained for the first time. The dendrochronological index of the avalanche activity, which is the ratio of the number of the tree growth failures to the number of the examined trees, is a good indicator of a release of a powerful avalanche even at a value of 0.85, provided that the number of examined trees in the lower part of the transit zone and in the zone of accumulation is 25–35 units. The results of this study may be used to predict the territorial differentiation of changes in the avalanche activity due to climate change. In connection with the recreational development of the Altai territory, they may also be of practical importance.

1. Benkova V. E., Schweingruber F. Kh. Anatomiya drevesiny ras­teniy Rossii. Anatomy of wood plants in Russia. Bern: Haupt, 2004: 465 p. [In Russian].

2. Bykov N. I. Lichenometric studies of avalanche processes in Altai. Izvestiya Altayskogo gosudarstvennogo universiteta. News of ASU. 1999, 3 (13): 29–32 [In Russian].

3. Bykov N. I. Dendrochronology of snow avalanches and at­mospheric circulation processes in the winter and tran­sitional periods in Altai. Problemy rekonstruktsii klimata i prirodnoy sredy golotsena i pleystotsena Sibiri. Problems of reconstruction of the climate and natural environ­ment of the Holocene and Pleistocene of Siberia. Novo­sibirsk: Publishing House of the Institute of Archeology and Ethnography of the Siberian Branch of the Russian Academy of Sciences. 2000, 2: 56–60 [In Russian].

4. Bykov N. I. Vegetation of avalanche collections of Altai and the possibilities of phytoindication of avalanche pro­cesses. Geografiya i prirodopol’zovaniye Sibiri. Geogra­phy and Nature Management of Siberia. 2013, 15: 23–31 [In Russian]

5. Bykov N. I. Avalanche collections of the river basin. Korgon (left tributary of the Charysh River) // Geografiya i priro­dopol’zovaniye Sibiri, Geography and Nature Manage­ment of Siberia. 2015, 19: 25–45 [In Russian].

6. Glyatsiologicheskiy slovar’. Glaciological Dictionary. Ed. V. M. Kotlyakov. Leningrad: Hydrometeoizdat, 1984: 526 p. [In Russian].

7. Koroleva T. V. Assessment of snowiness and avalanche dan­ger of Altai on a medium scale. Аvtoreferat dissertatsii na soiskaniye stepeni kandidata geograficheskikh nauk. Abstract of a dissertation for the degree of Candidate of Geographical Sciences: Abstract. PhD-thesis. Mos­cow: Lomonosov Moscow State University, 1993: 23 p. [In Russian].

8. Kravtsova V. I. Features of the regime of avalanche activity in the Altai according to dendrochronological obser­vations. Fitoindikatsionnyye metody v glyatsiologii. Phy­toindication methods in glaciology. Moscow: Moscow State University Publishing House.1971: 103–123 [In Russian].

9. Nikolaeva S. A., Savchuk D. A. Evaluation of dendroindica­tion methods for dating exogenous gravitational process­es of the past in the upper reaches of the river. Aktru (Gorny Altai). Izvestiya RAN. Seriya geograficheskaya. Proc. of the Russian Academy of Sciences. Geographic Series. 2021, 85 (3): 392–404 [In Russian].

10. Revyakin V. S., Kravtsova V. I. Snezhnyy pokrov i laviny Altaya. Snow cover and avalanches of Altai. Tomsk: Publish­ing House of Tomsk State University, 1976: 215 p. [In Russian].

11. Revyakin V. S. Prirodnyye l’dy Altaye-Sayanskoy gornoy oblas­ti. Natural ice of the Altai-Sayan mountain region. Len­ingrad: Hydrometeoizdat, 1981: 288 p. [In Russian].

12. Surnakov I. V. Some results of phytoindication of nival-gla­cial processes in Altai. Tezisy dokladov Vsesoyuznoy kon­ferentsii “Rol’ nival’no-glyatsial’nykh obrazovaniy v di­namike gornykh ekosistem”. Abstracts of the All-Union Conference “The role of nival-glacial formations in the dynamics of mountain ecosystems”. Barnaul: Barnaul: Publishing House of Altaysk State University, 1985: 35–36 [In Russian].

13. Surnakov I. V. Some information about the elements of the nival-glacial complex of the upper reaches of the Bolshoy Abakan River. Tezisy dokladov nauchno-prakticheskoy konferentsii “Ledniki i klimat Sibiri”. Abstracts of the reports of the scientific-practical conference “Glaciers and climate of Siberia”. Tomsk: Publishing House of Tomsk State University, 1987: 178–179 [In Russian].

14. Turmanina V. I. Dendrochronology of avalanches in the up­per reaches of the Baksan valley. Ritmy glyatsial’nykh protsessov. Rhythms of glacial processes. Moscow: Publishing House of Moscow State University, 1979: 128–134 [In Russian].

15. Germain D., Hétu B., Filion L. Tree-Ring Based Reconstruc­tion of Past Snow Avalanche Events and Risk Assess­ment in Northern Gaspé Peninsula (Québec, Canada). Tree Rings and Natural Hazards: A State-of-the-Art, Advances in Global Change Research. 2010, 41: 51–73. https://doi.org/10.1007/978-90-481-8736-2_5

16. Germain D. A statistical framework for treering reconstruc­tion of high-magnitude mass movements: case study of snow avalanches in Eastern Canada. Geografiska An­naler: Series A, Physical Geography. 2016, 98 (4): 303– 311. https://doi.org/10.1111/geoa.12138

17. Kaennel M., Schweingruber F. H. Multilingual Glossary of Dendrochronology. Bern, Stuttgart, Vienna: Haupt, 1995: 467 p.

18. Köse N., Aydın A., Yurtseven H., Akkemik Ü. Using tree-ring signals and numerical model to identify the snow av­alanche tracks in Kastamonu, Turkey. Natural Haz­ards. 2010, 54 (2): 435–449. https://doi.org/10.1007/s11069-009-9477-x

19. Laute K., Beylich A. A. Potential effects of climate change on future snow avalanche activity in western Norway deduced from meteorological data. Geografiska Annal­er: Ser. A. Physical Geography. 2018,100 (2): 163–184. https://doi.org/10.1080/04353676.2018.1425622

20. Martin J. P., Germain D. Can we discriminate snow av­alanches from other disturbances using the spatial patterns of tree-ring response? Case studies from the Presidential Range, White Mountains, New Hampshire, United States. Dendrochronologia. 2016, 37: 17–32. https://doi.org/10.1016/j.dendro.2015.12.004

21. Mundo I. A., Barrera M. D., Roig F. A. Testing the utili­ty of Nothofagus pumilio for dating a snow avalanche in Tierra del Fuego, Argentina. Dendrochronolo­gia. 2007, 25 (1): 19–28. https://doi.org//10.1016/j.dendro.2007.01.001

22. Perov V. F., Turmanina I., Akifeva K. V. Indications of av­alanches and mudflow by dendrochronology. Russian Papers on Dendrochronology and Dendroclimatelogy 1962, 1968, 1970, 1972. Research Laboratory for Arche­alogy and history of Art. Oxford University, 1977: 49–51.

23. Pop O. T., Munteanu A., Flaviu M., Gavrilă I. G., Timofte C., Holobâcă I. H. Tree-ring-based reconstruction of highmagnitude snow avalanches in Piatra Craiului Mountains (Southern Carpathians, Romania). Geo­grafiska Annaler: Series A, Physical Geography. 2017, 100 (7): 1–17. https://doi.org/10.1080/04353676.2017.1405715

24. Schweingruber F. H. Jahrringe und Umwelt — Dendrookologie. Birmensdorf: Eidgenoessische Forschungsanstalt fuer Wald, Schnee und Landschaft, 1993: 474 p.

25. Speer J. H. Fundamentals of Tree-Ring Research. Tucson: The University of Arizona Press, 2010: 509 p.

26. Tumajer J., Treml V. Reconstruction ability of dendrochro­nology in dating avalanche events in the Giant Moun­tains, Czech Republic. Dendrochronologia. 2015, 34: 1–9. https://doi.org/10.1016/j.dendro.2015.02.002

27. Zubairov B., Lentschke J., Schröder H. Dendroclimatology in Kazakhstan. Dendrochronologia. 2019, 56: 125602. https://doi.org/10.1016/j.dendro.2019.05.006