Preview

GEOGRAPHY, ENVIRONMENT, SUSTAINABILITY

Advanced search

Changes in the chemical composition of water in the SMALL Lake Vendyurskoe (Southern Karelia, Russia) over 50 years due to climate change and antropogenic impact

https://doi.org/10.24057/2071-9388-2026-4084

Abstract

Studies of changes in the chemical composition of lake water due to climate variability and human impact are highly relevant for Karelia, which has more than 60,000 lakes. Lake Vendyurskoe, a typical small lake in Karelia, has been used for growing rainbow trout since 2009. In the 1970–90s, drainage and logging were practiced in the catchment of this lake. A change in the composition of major ions in the lake’s water and an increase in the labile component of organic matter were observed between 1971 and 2023. In 2021–2023, the concentration of sulfate ions decreased fourfold compared to 1971–1985, which may be due to both the cessation of drainage operations and a reduction in the concentration of sulfates in precipitation. Chloride ion concentrations were reduced by half. The 50-year decrease in bicarbonate concentrations was likely associated with increased precipitation. Total phosphorus concentrations in the lake water showed an upward trend over the 50 years (in both surface and bottom layers), indicating increased anthropogenic impact on the lake. During the summer stratification period, hypoxia develops in the deep-water parts of the lake and near trout cages, and phosphate concentrations in the bottom layers are quite high (up to 36 μg/L). The mobilization of phosphorus from bottom sediments under anoxic conditions creates a secondary phosphorus load, which may be the reason for the increased bioproductivity. A direct correlation was found between the duration of near-bottom hypoxia in summer and the average air temperature over the three summer months (R2 = 0.51), suggesting deteriorating oxygen conditions in the lake during the open-water period as regional climate warming continues. The greatest oxygen depletion in the lake occurs in winters with early freeze-up and late ice-breaking. The inverse correlation of the duration of winter hypoxia with the November air temperature of the previous year (R2 = 0.39) and the May air temperature of the current year (R2 = 0.41), which influence the timing of ice formation and breakup, suggests the oxygen conditions in the lake during the winter have improved, with a shorter freeze-up period due to warming in the fall and spring. The observed changes in the water chemical composition provide reasoning for reducing the trout farming volumes.

About the Authors

A. V. Sabylina
Northern Water Problems Institute, Karelian Research Centre RAS
Russian Federation

50 Al. Nevsky Ave., Petrozavodsk, 185030



G. E. Zdorovenno
Northern Water Problems Institute, Karelian Research Centre RAS
Russian Federation

50 Al. Nevsky Ave., Petrozavodsk, 185030



T. A. Efremova
Northern Water Problems Institute, Karelian Research Centre RAS
Russian Federation

50 Al. Nevsky Ave., Petrozavodsk, 185030



R. E. Zdorovenno
Northern Water Problems Institute, Karelian Research Centre RAS
Russian Federation

50 Al. Nevsky Ave., Petrozavodsk, 185030



References

1. Adrian R., O’Reilly C. M., Zagarese H., Baines S. B., Hessen D. O., Keller W., Livingstone D. M., Sommaruga R., Straile D., Van Donk E., Weyhenmeyer G. A., and Winder M. (2009). Lakes as sentinels of climate change. Limnol Oceanogr., 54(6), 2283-2297. DOI: 10.4319/lo.2009.54.6_part_2.2283.

2. Alekin O. A. (1970). Fundamentals of hydrochemistry. L.: Gidrometeoizdat. 442 p. (in Russian).

3. Analytical, kinetic and calculation methods in hydrochemical practice. (2017). Ed. by P. A. Lozovik, N. A. Efremenko. St. Petersburg: Nestor-History. 272 p. (in Russian).

4. Bulygina O. N., Veselov V. M., Razuvaev V. N., and Aleksandrova T. M. (2025). Description of the array of urgent data on the main meteorological parameters at stations in Russia. Certificate of state registration of the database No. 2014620549 (in Russian).

5. Bush T., Diao M., Allen R.J., Sinnige R., Muyzer G., and Huisman J. (2017). Oxic-anoxic regime shifts mediated by feedbacks between biogeochemical processes and microbial community dynamics. Nat Commun., 8, 789 DOI:10.1038/s41467-017-00912-x

6. Dillon P. I. and Rigler F. N. (1974). A test of a simple nutrients budget model predicting the phosphorus concentrations in lake water. J. Fish. Res. Board Can., 31(11), 1771-1778, DOI: 10.1139/f74-225

7. Forsius M., Vuorenmaa J., Mannio J., and Syri S. (2003) Recovery from acidification of Finnish lakes: regional patterns and relations to emission reduction policy. Science of The Total Environment, 310(1–3), 121-132, DOI: 10.1016/S0048-9697(02)00628-9.

8. Freindling V. A. and Kharkevich N. S. (1982). Complex studies of the conditions for the formation of the regime of a number of small reservoirs in southern Karelia. Petrozavodsk. 28-31. (in Russian).

9. Galakhina N. E. and Zobkov M. B. (2022). Hydrochemical studies of the trout farming area in Kondopoga Bay of Lake Onego in the winter of 2022. Transactions of the Karelian Research Centre RAS, 6, 76–87. DOI: 10.17076/lim1599, (in Russian with English summary).

10. Grennfelt P., Engleryd A., Forsius M., Hov Ø., Rodhe H., and Cowling E. (2020). Acid rain and air pollution: 50 years of progress in environmental science and policy. Ambio, 49, 849–864. DOI:10.1007/s13280-019-01244-4

11. Gusakov B. L. (1987). Critical concentration of phosphorus in a lake tributary and its relationship with the trophic level of a reservoir. Coll. scientific. works. USSR Academy of Sciences, Institute of Limnology. Elements of the phosphorus cycle in reservoirs. Leningrad: Nauka, 1987. 7-17. (in Russian).

12. Hobbie J. E., Peterson B. J., Bettez N., Deegan L., O’Brien W. J., Kling G. W., Kipphut G. W., Bowden W. B., and Hershey A. E. (1999). Impact of global change on the biogeochemistry and ecology of an Arctic freshwater system. Polar Research. 18(2): 207–214. https://doi.org/10.3402/polar.v18i2.6576

13. Ilmast N. V., Kitaev S. P., Kuchko Ia. A., and Pavlovsky S.A. (2008). Hydroecology of lakes of different types in southern Karelia. Petrozavodsk, KarRC RAS, 2008. 92 p. (in Russian).

14. Jansen J., Simpson G. L., Weyhenmeyer G. A., Härkönen L. H., Paterson A. M., del Giorgio P. A., and Prairie Y. T. (2024). Climate-driven deoxygenation of northern lakes. Nat. Clim. Chang., 14, 832–838 DOI:10.1038/s41558-024-02058-3

15. Joung D., Leduc M., Ramcharitar B., Xu Y., Isles P. D. F., Stockwell J. D., Druschel G. K., Manley T., and Schroth A. W. (2017) Winter weather and lake-watershed physical configuration drive phosphorus, iron, and magnese dynamics in water and sediment of ice-covered lakes. Limnol. Oceanogr., 62(4), 1620-1635. DOI:10.1002/lno.10521

16. Karpechko Yu.V. (2004). Hydrological assessment of anthropogenic impact on watersheds in the taiga zone of the European North of Russia. Abstract of a diss. Doctor of Sciences in Geography. Petrozavodsk. 49 p. (in Russian).

17. Kharkevich N. S. and Kryukova P. V. (1981). Seasonal dynamics of mineralization and ionic composition of water in lakes of the Vendyurskoe-Vokhtozero group. In: Study and use of water resources. Petrozavodsk: Karelian branch of the USSR Academy of Sciences, 1981. 25-29. (in Russian).

18. Kharkevich N.S., Mitina I.F., and Kryukova P.V. (1982). On the hydrochemical regime of melioration canals in the catchment area of Lake Rindozero. In.: Studies of lake-river systems of Karelia. Operational information materials. Karelian branch of the USSR Academy of Sciences. p. 33-36. (in Russian).

19. Lakes of Karelia. Handbook. (2013). Ed. by N.N. Filatov, V.I. Kukharev. – Petrozavodsk: Karelian Research Center of the Russian Academy of Sciences. 464 p. (in Russian).

20. Lozovik P. (1994). Methods of water analysis in the hydrochemical laboratory of Northern Water Problems Institute, Petrozavodsk, Russian Karelia. Mimeogr., November 1994, 6 pp. (in Russian).

21. Lozovik P.A. (2006). Hydrogeochemical criteria for the state of surface waters in the humid zone and their resistance to anthropogenic impact. Abstract of a diss. Doctor of Sciences in Chemistry. Petrozavodsk: Karelian Research Center of the Russian Academy of Sciences, 2006. 56 p. (in Russian).

22. Lozovik P.A. and Potapova I.Yu. (2006) Input of chemical substances with atmospheric precipitation onto the territory of Karelia. Water Resources, 33(1), 104-111. DOI: 10.1134/S009780780601012X

23. Lozovik P.A., Efremenko N.A., and Basov S.V. (2006) Development of methods for chemical analysis of natural and polluted waters. In: Water resources of the European North of Russia: results and prospects of research. Proc. of the jubilee conference devoted to the 15th anniversary of NWPI. 92-110. (in Russian).

24. Maberly S.C., O’Donnell R.A., Woolway R.I., Cutler M. E. J., Gong M., Jones I. D., Merchant Ch. J., Miller C. A., Politi E., Scott E. M., Thackeray S. J., and Tyler A. N. (2020). Global lake thermal regions shift under climate change. Nat. Commun., 11, 1232, DOI:10.1038/s41467-020-15108-z

25. Martynova N.N. (1982). Chemical composition of atmospheric precipitation in the territory of the Syamozero basin of Karelia. In: Comprehensive study of water resources of Karelia. Petrozavodsk: Karelian branch of the USSR Academy of Sciences p. 33-35. (in Russian).

26. Mazoyer F. and Houle D. (2025) Long-term temporal response of eastern canadian lakes chemistry along a large spatial gradient of atmospheric sulfate deposition. Environmental Pollution, 366, 125498, DOI: 10.1016/j.envpol.2024.125498.

27. Mikhailenko V.G. and Sterligova O.P. (2021). Some ecological aspects of cage farming of rainbow trout. Proceedings of the Karelian Research Center of the Russian Academy of Sciences. Series: Ecological Research, 12, 82-90. DOI: 10.17076/eco1509 (in Russian).

28. Nazarova L.E. (2015). Precipitation over the territory of Karelia. Transactions of the Karelian Research Centre RAS, 9, 114-120. (in Russian with English summary).

29. Nazarova L.E., Isakova K.V., Kalinkina N.M., and Balaganskii A.F. (2022). The Climate Warming Influence on the Shuya River Winter Runoff and the Consequences for The Zoobenthos of the Onego Lake. Bulletin of the Russian Geographical Society, 154(1), 28-36. (in Russian with English summary).

30. Nürnberg G. K., Lazerte B. D., Loh P. S., and Molot L. A. (2013). Quantification of internal phosphorus load in large, partially polymictic and mesotrophic Lake Simcoe, Ontario. J. Great Lakes Res., 39, 271–279. DOI:10.1016/j.jglr.2013.03.017

31. O’Reilly C.M., Sharma S., Gray D.K., Hampton S. E., Read J. S., Rowley R. J., Schneider Ph., Lenters J. D., McIntyre P. B., Kraemer B. M., Weyhenmeyer G. A., Straile D., Dong B., Adrian R., Allan M. G., Anneville O., Arvola L., Austin J., Bailey J. L., Baron J. S., Brookes J. D., de Eyto E., Dokulil M. T., Hamilton D. P., Havens K., Hetherington A. L., Higgins S. N., Hook S., Izmest’eva L. R., Joehnk K. D., Kangur K., Kasprzak P., Kumagai M., Kuusisto E., Leshkevich G., Livingstone D. M., MacIntyre S., May L., Melack J. M., Mueller-Navarra D. C., Naumenko M., Noges P., Noges T., North R. P., Plisnier P.-D., Rigosi A., Rimmer A., Rogora M., Rudstam L. G., Rusak J. A., Salmaso N., Samal N. R., Schindler D. E., Schladow S. G., Schmid M., Schmidt S. R., Silow E., Soylu M. E., Teubner K., Verburg P., Voutilainen A., Watkinson A., Williamson C. E., and Zhang G. (2015). Rapid and highly variable warming of lake surface waters around the globe. Geophysical Research Letters, 42(24), 10,773-10,781 DOI:10.1002/2015GL066235.

32. Quinlan R., Filazzola A., Mahdiyan O., Shuvo A., Blagrave K., Ewins C., Moslenko L., Gray D. K., O’Reilly C. M., and Sharma S. (2021). Relationships of total phosphorus and chlorophyll in lakes worldwide. Limnol. Oceanogr. 66, 392–404, DOI:10.1002/lno.11611

33. Raspletina G.F. and Susareva O.M. (2002). Biogenic elements. In: Lake Ladoga – past, present, future. St. Petersburg: Nauka. p. 77-86. (in Russian).

34. Ryzhakov A.V., Kukkonen N.A., and Lozovik P.A. (2010). Determination of the rate of ammonification and nitrification in natural water by kinetic method. Water Resources, 37(1), 70-74. DOI: 10.1134/S0097807810010069

35. Ryzhakov A.V. (2020). Temperature dependence and activation parameters of ammonification and nitrification reactions in the water of Lake Onega. Ecological chemistry, 29(2), 65-70. (in Russian).

36. Sabylina A.V. and Basov M.I. (2003). Abiotic environmental factors, primary production and destruction of organic matter in Karelian water bodies. In: Hydroecological problems of Karelia and use of water resources. Petrozavodsk: Karelian Research Center of the Russian Academy of Sciences, p.72-91. (in Russian).

37. Sabylina A.V., Lozovik P.A., and Zobkov M.B. (2010). Water chemistry in Onega Lake and its tributaries. Water Resources, 37(6), 842-853, DOI: 10.1134/S0097807810060102.

38. Saros Ja.E., Arp Ch.D., Bouchard F., Comte J., Couture R.-M., Dean J. F., Lafrenière M., MacIntyre S., McGowan S., Rautio M., Prater C., Tank S. E., Walvoord M., Wickland K. P., Antoniades D., Ayala-Borda P., Canario J., Drake T. W., Folhas D., Hazuková V., Kivilä H., Klanten Y., Lamoureux S., Laurion I., Pilla R. M., Vonk J. E., Zolkos S., and Vincent W. F. (2023) Sentinel responses of Arctic freshwater system to climate: linkages, evidence, and a roadmap for future research. Arctic Science. 9(2), 356-392. DOI: 10.1139/as-2022-0021

39. Sharma S., Blagrave K., Magnuson J.J., O’Reilly C. M., Oliver S., Batt R. D., Magee M. R., Straile D., Weyhenmeyer G. A., Winslow L., and Woolway R. I. (2019). Widespread loss of lake ice around the Northern Hemisphere in a warming world. Nature Climate Change, 9 (3), 227-231, DOI: 10.1038/s41558-018-0393-5

40. Slastina Yu. L., Zdorovennova G. E., and Smirnova V. S. (2022). Structural and functional characteristics of phytoplankton of Lake Vendyurskoe affected by trout farm. Vestnik of Astrakhan State Technical University. Series: Fishing Industry, 1:22-31, DOI:10.24143/2073-5529-2022-1-22-31. (In Russian)

41. Smirnov S.I., Zdorovennov R.E., Efremova T.V., Palshin N. I., Smirnovsky A. A., Bogdanov S. R., Terzhevik A. Yu., and Zdorovennova G. E. (2024) Parameters of Water Column Stability in a Small Polymictic Lake in Years of Different Weather Conditions. Water Resources, 51, 299–313, DOI:10.1134/S0097807824700817.

42. Wik M., Varner R., Anthony K., MacIntyre S., and Bastviken D. (2016). Climate-sensitive northern lakes and ponds are critical components of methane release. Nature Geosci , 9, 99-105, DOI:10.1038/ngeo2578

43. Woolway R.I. and Merchant C.J. (2019). Worldwide alteration of lake mixing regimes in response to climate change. Nat. Geosci., 12, 271–276 DOI:10.1038/s41561-019-0322-x

44. Woolway R.I., Zhang Y., Jennings E., Zohary T., Jane S. F., Jansen J., Weyhenmeyer G. A., Long D., Fleischmann A., Feng L., Qin B., Shi K., Shi H., Wang W., Tong Y., Zhang G., Zscheischler J., Ren Z., and Jeppesen E. (2025). Extreme and compound events in lakes. Nat Rev Earth Environ 6, 593–611. DOI:10.1038/s43017-025-00710-w

45. Wu Z., Li J., Sun Y., Peñuelas J., Huang J., Sardans J., Jiang Q., Finlay J. C., Britten G. L., Follows M. J., Gao W., Qin B., Ni J., Huo S., and Liu Y. (2022). Imbalance of global nutrient cycles exacerbated by the greater retention of phosphorus over nitrogen in lakes. Nat. Geosci., 15, 464–468 DOI:10.1038/s41561-022-00958-7

46. Zhu L., Ju J., Qiao B., Liu C., Wang J., Yang R., Ma Q., Guo L., and Pang S. (2025). Physical and biogeochemical responses of Tibetan Plateau lakes to climate change. Nat Rev Earth Environ., 6, 284–298, DOI:10.1038/s43017-025-00650-5


Review

For citations:


Sabylina A.V., Zdorovenno G.E., Efremova T.A., Zdorovenno R.E. Changes in the chemical composition of water in the SMALL Lake Vendyurskoe (Southern Karelia, Russia) over 50 years due to climate change and antropogenic impact. GEOGRAPHY, ENVIRONMENT, SUSTAINABILITY. 2026;19(2):41-52. https://doi.org/10.24057/2071-9388-2026-4084

Views: 45

JATS XML


Creative Commons License
This work is licensed under a Creative Commons Attribution 4.0 License.


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