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«IZVESTIYA IRKUTSKOGO GOSUDARSTVENNOGO UNIVERSITETA». SERIYA «NAUKI O ZEMLE»
«THE BULLETIN OF IRKUTSK STATE UNIVERSITY». SERIES «EARTH SCIENCES»
ISSN 2073-3402 (Print)

List of issues > Series «Earth Sciences». 2025. Vol 53

Hydrological and Geomorphological Features of the Mudflows Formation on Mountain Rivers of the Slyudyansky District of the Irkutsk Region

Author(s)

N. V. Kichigina1, M.Yu. Opekunova1, 2

V. B. Sochava Institute of Geography SB RAS, Irkutsk, Russian Federation 

2 Irkutsk National Research Technical University, Irkutsk, Russian Federation

Abstract
The article studies the hydrological and geomorphological conditions of mudflow formation on the rivers of the Slyudyanka district based on an integrated approach. For this purpose, the analysis of maximum rainfall water discharge series for the period 1966–2022 was performed on the mudflow- and flood-hazardous rivers of the Khamar-Daban. The characteristics of suspended sediments on the rivers according to the data of hydrological posts are given. The characteristics of the relief structure of the territory are given. The geomorphological factors of the development of catastrophic floods and mudflows are identified. According to Roshydromet data, empirical probability curves and various options for its analytical approximation were constructed for each series of maximum discharges. The calculated values of maximum annual expenses of standard provisions were obtained. The years with high floods with the probability of maximum discharges below than 10 % were determined. The analysis of suspended sediments was performed for these years. The subjects of the study to identify hydrological and geological hazards are fluvial systems, their dynamic properties, spatial and temporal patterns of their functioning. Particularly destructive mudflows occasionally flow along the Slyudyanka, Bezymyannaya, Utulik, and Khara-Murin rivers. The following geomorphological factors have a significant impact on the formation of the solid component of the runoff of the territory under consideration: slope steepness, the proportion of deeply dissected relief (i.e., its energy), and the thickness of loose sediments subject to denudation processes and participating in sediment transport (for the basins under consideration, these are groups of slope processes). This study examines morphometric characteristics. The influence of slope length and steepness was taken into account using a combined relief function, which is used to quantify the relief factor when calculating the soil loss modulus – the LS factor. Conclusions were obtained that during the passage of mudflow floods of rare probability, the increase of water discharges occurs primarily due to the increase in flow velocity, which increased 4–9 times. High flow velocities create prerequisites for mudflow manifestations. The most destructive mudflow was in July 1971, when the probability of maximum water discharge on the rivers was 0.001–1.9 %, and the values of suspended sediment flow rates were the highest according to observations. A multiple increase in suspended sediment flow rates and turbidity occurs during the passage of maximum water discharge with a probability of 10 % and lower. The Bezymyannaya, Slyudyanka, Khara-Murin, and Utulik rivers have the most favorable geomorphological conditions for the development of mudflows and catastrophic floods. The Snezhnaya and Pokhabikha river basins have minimal average values of the considered indicators, which is explained by their minimum and maximum areas, respectively.
About the Authors

Kichigina Natalia Vitalievna, Candidate of Sciences (Geography), Senior Research Scientist Laboratory of Hydrology and Climatology V. B. Sochava Institute of Geography SB RAS 1, Ulan-Batorskaya st., Irkutsk, 664033 Russian Federation e-mail: nkichigina@mail.ru 

Opekunova Marina Yurievna, Candidate of Sciences (Geography), Senior Research Scientist, Laboratory of Geomorphology V. B. Sochava Institute of Geography SB RAS 1, Ulan-Batorskaya st., Irkutsk, 664033 Russian Federation Senior Research Scientist Irkutsk National Research Technical University 83, Lermontov st., Irkutsk, 664074, Russian Federation e-mail: opek@mail.ru

For citation
Kichigina N.V., Opekunova M.Yu. Hydrological and Geomorphological Features of the Mudflows Formation on Mountain Rivers of the Slyudyansky District of the Irkutsk Region. The Bulletin of Irkutsk State University. Series Earth Sciences, 2025, vol. 53, pp. 39-54. https://doi.org/10.26516/2073-3402.2025.53.39 (in Russian)
Keywords
mudflows, rainfall floods, maxima discharge, mountains rivers, hydrological and morphological analysis, Slyudyansky district.
UDC
556.53(571.53)
DOI
https://doi.org/10.26516/2073-3402.2025.53.39
References
  1. Agafonov B.P. Ekzolitodinamika Baikalskoi riftovoi zony [Exolithodynamics of the Baikal rift zone]. Novosibirsk, Nauka Publ., 1990, 176 p. (in Russian) 
  2. Atlas Irkutskoi oblasti: Ekologicheskie usloviya razvitiya [Atlas of the Irkutsk Region: Ecological Conditions of Development. Eds. V.V. Vorobyov, A.N. Antipov, V.F. Khabarov. Irkutsk, Institute of Geography SB RAS Publ., Moscow, Roskartografiya Publ., 2004, 90 p. (in Russian) 
  3. Budz M.D. Usloviya formirovaniya selei v Pribaikal'e [Mudflow conditions in the Baikal region]. Opolzni, seli, termokarst v Vostochnoi Sibiri i ikh inzhenerno-geologicheskoe znachenie [Landslides, mudflow formation, thermokarst in the east of Siberia and their engineering-geological significance]. Moscow, Nauka Publ., 1969, pp. 60-95. (in Russian) 
  4. Vinogradov Ju.B. Matematicheskoe modelirovanie processov formirovanija stoka: Opyt kriticheskogo analiza. [Mathematical modeling of runoff formation processes: Experience of critical analysis]. Leningrad, Gidrometeoizdat Publ., 1988, 312 p. (in Russian) 
  5. Vyrkin V.B. Sovremennoe ekzogennoe rel'efoobrazovanie kotlovin baikal'skogo tipa [Modern exogenous relief formation of basins of the Baikal type]. Irkutsk, IG SB RAS Publ., 1998, 175 p. (in Russian) 
  6. Ivanovsky L.N. Osobennosti razvitiya dolin na yuzhnom poberezh'e Baikala v antropogene [Features of the development of valleys on the southern coast of Lake Baikal in the anthropogene]. Istoriya razvitiya rechnykh dolin i problemy melioratsii zemel. Sibir i Dalnii Vostok [History of the development of river valleys and problems of land reclamation. Siberia and the Far East]. Novosibirsk, Nauka Publ., 1979, pp. 55-62. (in Russian) 
  7. Litvin V.M. Opyt regionalnoi otsenki intensivnosti proyavleniya ekzogennykh geologicheskikh protsessov na yuge Vostochnoi Sibiri [Experience of regional assessment of intensity of manifestation of exogenous geological processes in the south of Eastern Siberia]. Inzhenernaya geologiya [Engineering Geology], 1991, no.. 6, pp.72–81. (in Russian)
  8. Makarov S. A. Seli Pribaikal'ya [Debris Flows inCis-Baikalia]. Irkutsk, IG SB RAS Publ., 2012, 111 p. (in Russian) 
  9. Mats V.D., Ufimtsev G.F., Mandelbaum M.M. Kainozoi Baikalskoi riftovoi vpadiny. Stroenie I geologicheskaya istoriya [Cenozoic of the Baikal Rift Basin. Structure and Geological History]. Novosibirsk, SB RAS GEO Publ., 2001, 251 p. (in Russian) 
  10. Laperdin V.K., Levi K.G., Imaev V.S., Molochny V.G. Opasnye geologicheskie protsessy v Yugo-Zapadnom Pribaikal'e [Dangerous geological processes in the South-West Baikal region]. Irkutsk, Institute of the Earth's Crust SB RAS Publ., 2016, 199 p. (in Russian) 
  11. Khromovskikh V.S. Seismogeologiya Yuzhnogo Pribaikal'ya [Seismogeology of the Southern Baikal region]. Moscow, Nauka, Publ. , 1965. 122 p. (in Russian) 
  12. Alekseevskiy N.I., Berkovich K.M., Chalov R.S. Erosion, sediment transportation and accumulation in rivers. International Journal of Sediment Research, 2008, vol. 23, no. 2, pp. 93-105. 
  13. Beven, K.J., Kirkby, M.J. A physically-based variable contributing area model of basin hydrology. Hydrology Science Bulletin, 1979, vol. 24, no. 1, pp. 43-69. 
  14. Boehner, J., Selige, T. Spatial Prediction of Soil Attributes Using Terrain Analysis and Climate Regionalisation. SAGA – Analysis and Modelling Applications, Goettinger Geographische Abhandlungen, 2006, vol. 115, pp. 13-27. 
  15. Chalov R.S. Comparative analysis of channel processes on mountain, semi-mountain and plain rivers. Geography and Natural Resources, 2008, vol. 29, no. 1, pp. 28-35. 
  16. Chalov R.S. Sediment runoff, transporting capacity of flows and their role in river channel formation. Geography and Natural Resources, 2011, vol. 32, no. 3, pp. 220-225. 
  17. Chen C.-Y., Yu F.-C. Morphometric analysis of debris flows and their source areas using GIS. Geomorphology, 2011, vol. 129, pp. 387-397. 
  18. Fan R.L., Zhang L.M., Wang H.J., Fan X.M. Evolution of debris flow activities in Gaojiagou Ravine during 2008–2016 after the Wenchuan earthquake. Engineering Geology, 2018, vol. 235, pp. 1-10. 
  19. Kinnell P.I.A. Alternative Approaches for Determining the USLE-M Slope Length Factor for Grid Cells. Sci. Soc. Am. J., 2005, vol. 60, no. 3, pp. 674-680. Moore, I.D., Grayson, R.B., Ladson, A.R. Digital terrain modelling: a review of hydrogical, geomorphological, and biological applications. Hydrological Processes, 1991, vol. 5, no. 1, pp. 3-30. 
  20. Chalov R.S., Kamyshev A.A., Kurakova A.A., Zavadskii A.S. The distribution of water and suspended sediment flow during spring flood in the forked channel of the lower ob (within Khanty-Mansi autonomous area). Water Resources, 2021, vol. 48, no. 1, pp. 18-28. 
  21. Wang L., Liu N. An efficient method for identifying and filling surface depressions in digital elevation models for hydrologic analysis and modelling. Int. J. Geogr. Inf. Sci., 2006, vol. 20, no. 2, pp. 193-213. 



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