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Changes in annual river flow in the Volga–Kama and Angara–Yenisei reservoir basins under contemporary and scenario global warming

https://doi.org/10.24057/2071-9388-2026-4228

Abstract

The paper presents a study of annual runoff and water availability changes in the Volga–Kama and Angara–Yenisei reservoir basins under contemporary and mid-21st century scenario global anthropogenic warming. The estimates of changes are based on a comparison of runoff under global warming and for the reference period, calculated from observational data and averaged results of its calculation performed with an ensemble of global climate models. During the period of contemporary global warming, the average long-term annual runoff and water availability per unit area and per capita increased, especially in the Volga–Kama reservoir basins, with the exception of the Volgograd reservoir basin, where they decreased sharply. The observed and average model annual runoff in the considered reservoir basins is closely correlated for contemporary global warming as well as for baseline periods. However, for a fairly significant number of basins, the model runoff differs significantly from the observed value. The observed and model difference in the runoff of the two compared periods differs significantly in the Volga–Kama as well as in Angara–Yenisei reservoir basins. Nevertheless, the sign of the difference is the same in almost all basins. In 2040–2069 the annual runoff under varying intensity warming scenarios may increase relative to the model reference period runoff in all reservoir basins of the Angara–Yenisei cascade, whereas in the Volga–Kama reservoir basins the probable runoff changes are likely to have different signs relative to the runoff of the reference period. In most basins the per capita scenario water availability is likely to increase by varying degrees, partly owing to the probable population decline.

About the Authors

A. G. Georgiadi
Institute of Geography Russian Academy of Sciences
Russian Federation

Staromonetny lane, Moscow, 119017



E. A. Barabanova
Institute of Geography Russian Academy of Sciences
Russian Federation

Staromonetny lane, Moscow, 119017



I. P. Milyukova
Institute of Geography Russian Academy of Sciences
Russian Federation

Staromonetny lane, Moscow, 119017



A. N. Narykov
Institute of Geography Russian Academy of Sciences
Russian Federation

Staromonetny lane, Moscow, 119017



P. A. Morozova
Institute of Geography Russian Academy of Sciences
Russian Federation

Staromonetny lane, Moscow, 119017



References

1. Anisimov O.A. and Kokorev V.A. (2013). The optimal choice of hydrodynamic models to assess the impact of climate change on the cryosphere, Ice and Snow, 53(1), 83-92 (in Russian with English summary), DOI: 10.15356/2076-6734-2013-1-83-92.

2. Babina E.D. and Georgiadi A.G. (2016). Assessment of the quality of reproduction of air temperature and precipitation amounts in the Lena River basin by global climate models, Vestn. Mosk. Univ., ser. 5, Geogr, 5, 69–76 (in Russian with English summary).

3. Barabanova E.A. (2004). Comparison of reservoirs by the complex of their positive and negative impacts on the environment and economy. Izvestiya Rossiiskoi Akademii Nauk. Seriya Geograficheskaya, 2, 72–82. (In Russian with English summary).

4. Eyring V., Bony S., Meehl G. A., Senior C. A., Stevens B., Stouffer R. J. and Taylor K. E. (2016). Overview of the Coupled Model Intercomparison Project Phase 6 (CMIP6) experimental design and organization. Geosci. Model Dev., 9, 1937–1958, DOI: 10.5194/gmd-9-1937-2016, 2016a.

5. Frolova N.L., Magritskii D.V., Kireeva M.B., Grigor’ev V.Y., Gelfan A.N., Sazonov A.A.and Shevchenko A.I. (2022). Streamflow of the Russian rivers under current and forecasted climate changes. A review of publications. 1. Assessment of changes in the water regime of Russian rivers by observation data. Water Resour., 49(3), 333-350, DOI: 10.1134/S0097807822030046.

6. Georgiadi A.G. and Kashutina Ye.A. (2014). The Features of Long-term Annual and Seasonal Runoff Changes for Lena Basin Rivers. Izvestiya Rossiiskoi Akademii Nauk. Seriya Geograficheskaya, (2), 71-83, DOI: 10.15356/0373-2444-2014-2-71-83 (in Russian with English summary).

7. Georgiadi A.G. and Kashutina E.A. (2016). Long-term changes in the runoff of the largest Siberian rivers. Izvestiya Rossiiskoi Akademii Nauk. Seriya Geograficheskaya, 5, 70–81, doi: 10.15356/0373-2444-2016-5-70-81 (in Russian with English summary)

8. Georgiadi A.G. and Milyukova I.P. (2023). Volga runoff in the era of global warming. Izvestiya Rossiiskoi Akademii Nauk. Seriya Geograficheskaya, 87(6), 804–824, DOI: 10.31857/S2587556623060079 (in Russian with English summary).

9. Georgiadi, A.G., Koronkevich N.I., Barabanova E.A. and Melnik K.S. (2021). Water resources and water-ecological stress in the Central Federal District of Russia. Izvestiya Rossiiskoi Akademii Nauk. Seriya Geograficheskaya, 85(3), 325-340, DOI: 10.31857/S2587556621030079 (in Russian with English summary).

10. Georgiadi A.G., Milyukova I.P., Borodin O.O. and Barabanova E.A. (2024). Water Flow of the Largest Russian Rivers in Modern and Scenario Global Warming. Izvestiya Rossiiskoi Akademii Nauk. Seriya Geograficheskaya, 88(6), 855-866, DOI: 10.31857/S2587556624060011. (in Russian with English summary).

11. Georgiadi A.G., Milyukova I.P., Borodin O.O. and Gusarov A.V. (2023). Water flow changes in the Don River (European Russia) during 1891–2019. Geography, Environment, Sustainability, 16(2), 6-17, DOI: 10.24057/2071-9388-2022-083.

12. Georgiadi A.G., Koronkevich N.I., Milyukova I.P., Kashutina E.A. and Barabanova E.A. (2014). Contemporary and Scenario Changes in River Runoff in the Basins of the Largest Russian Rivers. Part 2. Basins of the Volga and Don. Moscow: Maks Press Publ. (in Russian).

13. Georgievskii V.Yu. ed. (2017). Scientific and applied reference book: Long-term characteristics of water inflow into the largest reservoirs of the Russian Federation. Moscow: OOO «APC Ofort» Publ. (in Russian).

14. Georgievskii V.Yu. and Moiseenkov A.I. (1984). Restoration of natural hydrographs of the flow of large rivers, regulated by a cascade of reservoirs (on the example of the Volga River). Proc. SHI, 291, 54-61. (In Russian).

15. Georgievsky M.V. and Golovanov O.F. (2015). Assessment of probable changes in runoff in the Amur River basin for the period up to 2020 and 2050 based on data from atmospheric and ocean general circulation models. In: Georgievskii, V.Yu., ed., Extreme Floods in the Amur Basin: Hydrological Aspects. St. Petersburg: OOO EsPeKha Publ., 153–179. (in Russian).

16. Georgievsky M.V. and Golovanov O.F. (2019). Forecasting changes in river water resources of Russian Federation based on CMIP5 runoff data. Vestnik of Saint Petersburg University. Earth Sciences, 64 (2), 206–218, DOI: 10.21638/spbu07.2019.203 (In Russian with English summary).

17. Guo H., Zhan C., Ning L., Li X., Hu S. (2022). Evaluation and comparison of CMIP6 and CMIP5 model performance in simulating the runoff. Theor. Appl. Climatol., 149, 1451–1470, DOI: 10.1007/s00704-022-04118-0

18. Kalinin G.P. and Milyukov P.I. (1958). Approximate Calculation of Unsteady Motion of Water Masses. Proceedings of the Central Institute of Forecasts. Issue 66. Leningrad: Gidrometeoizdat, 72 (In Russian).

19. Kalugin A. (2023). Climate change effects on river flow in Eastern Europe: Arctic rivers vs. Southern rivers. Climate, 2023, 11 (103), doi: 10.3390/cli11050103

20. Kattsov V.M. and Govorkova V.A. (2013). Expected surface air temperature, precipitation and annual runoff changes over the territory of Russia: projections with an ensemble of global climate models (cmip5). Trudy GGO, (569), 75–97. (In Russian).

21. Kislov A.V., Evstigneev V.M., Malkhazova S.M., et al. (2008). Forecast of Climatic Resource Availability of the East European Plain in the Conditions of Warming of the 21st Century. Moscow: Max Press. (In Russian).

22. Koronkevich N.I., Barabanova Ye.A., Bibikova T.S. and Zaitseva I.S. (2014). Russia on the world map of water use, Izvestiya RAN. Seriya Geograficheskaya, 1, 7–18 (in Russian with English summary).

23. Kuzin P.S. (1960). Classification of Rivers and Hydrological Zoning of the USSR. Leningrad: Gidrometeoizdat. (In Russian).

24. Kuzin P.S. and Babkin V.I. (1979). Geographical Regularities of the Hydrological Regime of Rivers. Leningrad: Gidrometeoizdat. (In Russian).

25. Menzhulin G.V., Shamshurin V.I., and Savvateev S.P. (2005). On the assessment of the accuracy of model climate change scenarios recommended by the IPCC commission for calculating the consequences of global warming. In: Modern Problems of Environmental Meteorology and Climatology. St. Petersburg: Nauka Publ., 55–85. (In Russian).

26. Milyukova I.P., Georgiadi A.G. and Borodin O.O. (2020). Long-term changes in water flow of the Volga basin rivers. E3S Web of Conferences 163, 05008, DOI: 10.1051/e3sconf/202016305008.

27. Mokhov I.I., Semenov V.A. and Khon V.K. (2003). Estimates of possible regional hydrologic regime changes in the 21st century based on global climate models. Izvestiya Rossiiskoi Akademii Nauk. Seriya Atmospheric and Oceanic Physics, (39), 130–144. (In Russian).

28. Motovilov Yu. G. and Gelfan A. N. (2019). Runoff Formation Models in Challengers of River Basin Hydrology. Moscow: Izdatel’stvo Rossiiskoi Akademii Nauk (In Russian).

29. O’Neill B. C., Tebaldi C., van Vuuren D. P., Eyring V., Friedlingstein P., Hurtt G., Knutti R., Kriegler E., Lamarque J.-F., Lowe J., Meehl G. A., Moss R., Riahi K., and Sanderson B. M. (2016). The Scenario Model Intercomparison Project (ScenarioMIP) for CMIP6. Geosci. Model Dev., [online] 9, 3461–3482. Available at: https://doi.org/10.5194/gmd-9-3461-2016 [Accessed 26 Aug. 2025].

30. Shiklomanov A.I., Golovanov O., Lammers R.B., Tretjyakov M. & Yang D. (2011). Dam/Reservoir-Induced Hydrological Changes in Large Siberian Rivers. Amer. Geophys. Union, Fall Meeting 2011, Abstract C31B-06.

31. Shiklomanov I.A. ed. (2008). Water Resources of Russia and Their Use. Saint-Petersburg: State Hydrological Institute Publ. (in Russian).

32. Shpakova R.N., and Wang P. (2023). Change in Perennial Runoff Fluctuations of the Rivers in South Yakutia in the Context of Global Warming. Russian Arctic, 5(1), 33-44, DOI: 10.24412/2658-4255-2023-1-33-44 (In Russian).

33. Sinyukovich V.N., Georgiadi A.G., Groisman P.Y., Borodin O.O., and Aslamov I.A. (2024). The Variation in the Water Level of Lake Baikal and Its Relationship with the Inflow and Outflow. Water, 16, 560. https://doi.org/10.3390/w16040560.

34. Yang D. and Kane D.L. (Еds.) (2021). Arctic Hydrology, Permafrost and Ecosystems. Cham: Springer, DOI: 10.1007/978-3-030-50930-9.


Review

For citations:


Georgiadi A.G., Barabanova E.A., Milyukova I.P., Narykov A.N., Morozova P.A. Changes in annual river flow in the Volga–Kama and Angara–Yenisei reservoir basins under contemporary and scenario global warming. GEOGRAPHY, ENVIRONMENT, SUSTAINABILITY. 2026;19(2):233-244. https://doi.org/10.24057/2071-9388-2026-4228

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ISSN 2071-9388 (Print)
ISSN 2542-1565 (Online)