Article

Article name BEAVER IMPACT ON WATER COVERAGE OF FOREST-STEPPE TERRITORIES (PENZA REGION, EUROPEAN RUSSIA)
Authors

Ivan V. Bashinskiy, PhD, Senior Researcher in Laboratory for Ecology of Aquatic Communities and Invasions, A.N. Severtsov Institute of Ecology and Evolution RAS, (119071, Russia, Moscow, Leninskiy prospect, 33); https://orcid.org/0000-0002-2927-406x; e-mail: ivbash@mail.ru

Reference to article

Bashinskiy I.V. 2021. Beaver impact on water coverage of forest-steppe territories (Penza Region, European Russia). Nature Conservation Research 6(1): 88–97. https://dx.doi.org/10.24189/ncr.2021.016

Section Research articles
DOI https://dx.doi.org/10.24189/ncr.2021.016
Abstract

The impact of the European beaver (Castor fiber) on the water coverage of natural territories was assessed by analysing public available satellite images. Four model squares with a total area of 900 km2 were chosen, with coverage of the vicinity of four sectors of the Privolzhskaya Lesostep' State Nature Reserve (Penza region). This study showed that modern public satellite images can clearly distinguish beaver ponds even of small sizes, as well as elements of their activity, namely beaver dams, canals and tracks. We identified 373 water bodies that were made by beavers, with an average area of 1040 ± 4843 m2, 107 man-made ponds (average area 24 272 ± 65 977 m2), and 67 lakes and oxbows (average area 8127 ± 17 946 m2). The proportion of zoogenic ponds was 11% of the total area and 68% of the total number. In certain study sites, these values varied from 7% to 18% (for the area) and from 44% to 84% (for the number). But within the boundaries of the Privolzhskaya Lesostep' State Nature Reserve, where there were no man-made water bodies, the proportion of beaver ponds reached 100% in three sectors. The total water body' area percentage of the studied territories was 0.39%. In different sites, beavers increased the proportion of water bodies by 0.02–0.10%, in total by 0.04%. If we consider only the area of natural water bodies, then beavers increased it in 1.7 times, while within the boundaries of the Privolzhskaya Lesostep' State Nature Reserve this increase was 3.6 times. Since the water coverage of the central regions of European Russia was considerably increased due to the construction of man-made ponds, this could affect the structure of habitats in the floodplains of small rivers, and favour the activity of beavers in the forest-steppe regions. Therefore, there was a slight correlation between the number and area of beaver ponds and the size of downstream man-made water bodies. Our data have shown that the zoogenic contribution to water resources is comparable to the contribution of natural lakes and ponds. In some areas with low anthropogenic impact, water bodies created by beavers are the only lentic habitats in the landscape. However, the obtained results do not completely cover the real beaver impact, since narrow channel-like ponds hidden by the canopy of floodplain trees fall out of analysis. It is impossible to take into account the length of the backwater zone with a cascade of zoogenic water bodies, neither is it possible to remotely assess the contribution of animals to the retention capacity of old man-made ponds, and the role of the ecological engineer in maintaining and increasing the surface area of pre-existing lakes. Therefore, the contribution of beavers to the water coverage of the territory is actually more remarkable.

Keywords

Castor fiber, lake, man-made pond, Privolzhskaya Lesostep' State Nature Reserve, remote methods, water body area percentage, water resources, zoogenic pond

Artice information

Received: 06.11.2020. Revised: 22.01.2021. Accepted: 28.01.2021.

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References

Bashinskiy I.V., Osipov V.V. 2016. Beavers in Russian forest-steppe – characteristics of ponds and their impact on fishes and amphibians. Russian Journal of Theriology 15(1): 34–42. DOI: 10.15298/rusjtheriol.15.1.06
Bashinskiy I.V., Osipov V.V. 2018. Distribution and dynamic of Castor fiber (Castoridae, Mammalia) population in forest-steppe rivers: a case of the State Nature Reserve Privolzhskaya Lesostep', Penza region, European Russia. Nature Conservation Research 3(Suppl.2): 110–115. DOI: 10.24189/ncr.2018.068
Bashinskiy I.V., Senkevich V.A., Stoyko T.G., Katsman E.A., Korkina S.A., Osipov V.V. 2019. Forest-steppe oxbows in limnophase – Abiotic features and biodiversity. Limnologica, 74: 14–22. DOI: 10.1016/j.limno.2018.10.005
Bouwes N., Weber N., Jordan C.E., Saunders W.C., Tattam I.A., Volk C., Wheaton J., Pollock M.M. 2016. Ecosystem experiment reveals benefits of natural and simulated beaver dams to a threatened population of steelhead (Oncorhynchus mykiss). Scientific Reports 6: 28581. DOI: 10.1038/srep28581
Buchik S.V., Dmitireva V.A. 2019. Hydroecological consequences of seasonal changes in the water amount of rivers in the upper Don basin. In: Scientific problems of the improvement of Russian rivers and ways of their solution. Moscow: Studiya F1. P. 309–313. [In Russian]
CCM. 2020. Catchment Characterization and Modelling. Joint Research Centre. The European Commission's in-house science service. Available from https://ccm.jrc.ec.europa.eu/php/index.php?action=view&id=24
Céréghino R., Boix D., Cauchie H.M., Martens K., Oertli B. 2013. The ecological role of ponds in a changing world. Hydrobiologia 723(1): 1–6. DOI: 10.1007/s10750-013-1719-y
Chernova М.А., Dudnik S.N., Bukovsky М.Е. 2020. Variability of the water regime in the Don basin rivers. Proceedings of Voronezh State University. Series: Geography. Geoecology 3: 40–48. DOI: 10.17308/geo.2020.3/3022 [In Russian]
Dalbeck L., Janssen J., Völsgen S.L. 2014. Beavers (Castor fiber) increase habitat availability, heterogeneity and connectivity for common frogs (Rana temporaria). Amphibia-Reptilia 35(3): 321–329. DOI: 10.1163/15685381-00002956
Dalbeck L., Hachtel M., Campbell-Palmer R. 2020. A review of the influence of beaver Castor fiber on amphibian assemblages in the floodplains of European temperate streams and rivers. Herpetological Journal 30(3): 135–146. DOI: 10.33256/hj30.3.135146
Dmitrieva V.A. 2011. Change in the river network and water resources in the upper and middle reaches of the Don River due to current climatic and economic conditions. Arid Ecosystems 1(3): 193– 199. DOI: 10.1134/S2079096111030048
Dmitrieva V.A. 2020. Modern changes in the water regime and the morphometry of rivers in the upper Don basin. Izvestiya Rossiiskoi Akademii Nauk. Seriya Geograficheskaya 1: 103–113. DOI: 10.31857/S2587556620010070 [In Russian]
Dobrolyubov A.N., Lebyazhinskaya I.P., Kudryavtsev A.Yu., Gorbushina T.V., Dobrolyubova T.V., Osipov V.V. 2013. The State Nature Reserve «Privolzhskaya Lesostep'»: physical and geographical characteristics and biological diversity of natural complexes. Proceedings of the State Nature Reserve «Privolzhskaya Lesostep» 4: 1–70. [In Russian]
Dobrov A.I. 2000. About of interaction of ponds and reservoirs with adjacent landscapes. Proceedings of Voronezh State University 4: 153–156. [In Russian]
Downing J.A. 2010. Emerging global role of small lakes and ponds: little things mean a lot. Limnetica 29(1): 9–24. DOI: 10.23818/limn.29.02
Dyakonov K.N., Anoshko V.S. 1995. Land melioration geography. Moscow: Moscow State University. 254 p. [In Russian]
Elpiner L.I., Bear S.A., Zektser I.S., Klige R.K., Shapovalov A.E. 2007. The effect of water abundance in a territory on the population health. Water Resources 34(3): 340–349. DOI: 10.1134/S0097807807030128
Frolova N.L., Kireyeva M.B., Agafonova S.A., Yevstigneyev V.M., Yefremova N.A., Povalishnikova Y.S. 2015. Lowland rivers runoff within-year distribution and changes on the European territory of Russia. Water sector of Russia: problems, technologies, management 4: 4–20. [In Russian]
Gatti R., Callaghan T.V., Rozhkova-Timina I., Dudko A., Lim A., Vorobyev S.N., Kirpotin S.N., Pokrovsky O.S. 2018. The role of Eurasian beaver (Castor fiber) in the storage, emission and deposition of carbon in lakes and rivers of the River Ob flood plain, Western Siberia. Science of the Total Environment 644: 1371–1379. DOI: 10.1016/j.scitotenv.2018.07.042
Goryainova Z.I., Petrosyan V.G., Zavyalov N.A. 2012. Potential capabilities of space images of average (Landsat 7) very high (Ikonos, Geoeye-1) resolution for mapping activities objects. In: European beaver (Castor fiber L.) as a key species of a small river ecosystem (Prioksko-Terrasnyi State Nature Biosphere Reserve). Moscow: KMK Scientific Press Ltd. P. 128–137. [In Russian]
Goryainova Z.I., Petrosyan V.G., Zavyalov N.A. 2018. Using of Geoeye-1 satellite data to study the influence of the engineering activity of the Eurasian beaver (Castor fiber L.) on riparian forest landscapes. In: V.G. Sychev, L. Mueller (Eds.): Novel methods and results of landscape research in Europe, Central Asia and Siberia. Мoscow: Publishing House «Pryanishnikov Institute of Agrochemistry». P. 148–152. [In Russian]
Grygoruk M., Nowak M. 2014. Spatial and temporal variability of channel retention in a lowland temperate forest stream settled by European beaver (Castor fiber). Forests 5(9): 2276–2288. DOI: 10.3390/f5092276
Halley D.J., Saveljev A.P., Rosell F. 2021. Population and distribution of beavers Castor fiber and Castor canadensis in Eurasia. Mammal Review 51(1): 1–24. DOI: 10.1111/mam.12216
Hood G.A., Bayley S.E. 2008. Beaver (Castor canadensis) mitigate the effects of climate on the area of open water in boreal wetlands in western Canada. Biological Conservation 141(2): 556–567. DOI: 10.1016/j.biocon.2007.12.003
Izmailova A.V. 2016. Water resources of the Lakes of Russia. Geography and Natural Resources 37: 281–289. DOI: 10.1134/S1875372816040016
Izmailova A.V. 2018. The lake fund of the Russian Federation and it`s quantitative changes. In: V.P. Solomin, V.A. Rumyantsev, D.A. Subetto, N.V. Lovelius (Eds.): Geography: development of science and education. Vol. 1. St. Petersburg: A.I. Herzen Russian State Pedagogical University Publishing House. P. 310–314.
Izmailova A.V., Korneenkova N.Y. 2020. Lake Area Percentage in Russian Federation Territory and Its Governing Factors. Water Resources 47(1): 13–21. DOI: 10.1134/S009780782001008X
Johnston C.A., Naiman R.J. 1990. The use of a geographic information system to analyze long-term landscape alteration by beaver. Landscape Ecology 4(1): 5–19. DOI: 10.1007/BF02573947
Karran D.J., Westbrook C.J., Bedard-Haughn A. 2018. Beaver-mediated water table dynamics in a Rocky Mountain fen. Ecohydrology 11(2): e1923. DOI: 10.1002/eco.1923
Kirikov S.V. 1966. Game animals, natural environment and humans. Moscow: Nauka. 347 p. [In Russian]
Kitaev S.P. 2007. Fundamentals of limnology for hydrobiologists and ichthyologists. Petrozavodsk: Karelian Scientific Centre of RAS. 395 p. [In Russian]
Law A., Levanoni O., Foster G., Ecke F., Willby N.J. 2019. Are beavers a solution to the freshwater biodiversity crisis? Diversity and Distributions 25(11): 1763–1772. DOI: 10.1111/ddi.12978
Lazar J.G., Addy K., Gold A.J., Groffman P.M., McKinney R.A., Kellogg D.Q. 2015. Beaver Ponds: Resurgent Nitrogen Sinks for Rural Watersheds in the Northeastern United States. Journal of Environmental Quality 44(5): 1684–1693. DOI: 10.2134/jeq2014.12.0540
Martin S.L., Jasinski B.L., Kendall A.D., Dahl T.A., Hyndman D.W. 2015. Quantifying beaver dam dynamics and sediment retention using aerial imagery, habitat characteristics, and economic drivers. Landscape Ecology 30(6): 1129–1144. DOI: 10.1007/s10980-015-0165-9
Morrison A., Westbrook C.J., Bedard-Haughn A. 2015. Distribution of Canadian Rocky Mountain wetlands impacted by beaver. Wetlands 35(1): 95–104. DOI: 10.1007/s13157-014-0595-1
Nummi P., Holopainen S. 2014. Whole-community facilitation by beaver: ecosystem engineer increases waterbird diversity. Aquatic Conservation: Marine and Freshwater Ecosystems 24(5): 623–633. DOI: 10.1002/aqc.2437
Osipov V.V., Bashinskiy I.V. 2018. Beavers in the State Nature Reserve «Privolzhskaya Lesostep». Proceedings of State Nature Reserve «Rdeysky» 4: 337–353. [In Russian]
Osipov V.V., Bashinskiy I.V., Podshivalina V.N. 2018. Influence of the activity of the Eurasian Beaver Castor fiber (Castoridae, Mammalia) on the ecosystem biodiversity of small rivers in the forest–steppe zone. Biology Bulletin 45(10): 23–32. DOI: 10.1134/S1062359018100205
Puttock A., Graham H.A., Cunliffe A.M., Elliott M., Brazier R.E. 2017. Eurasian beaver activity increases water storage, attenuates flow and mitigates diffuse pollution from intensively-managed grasslands. Science of the Total Environment 576: 430–443. DOI: 10.1016/j.scitotenv.2016.10.122
Pankova N.L., Pankov A.B. 2010. Beaver (Castor fiber) usage mode of the Pra river plain reservoirs in the Oka Nature Reserve. Povolzhskiy Journal of Ecology 3: 291–301. [In Russian]
Pollock M.M., Lewallen G., Woodruff K., Jordan C.E., Castro J.M. 2015. The Beaver Restoration Guidebook: Working with Beaver to Restore Streams, Wetlands, and Floodplains. Version 1.02. Portland: United States Fish and Wildlife Service. 189 p.
Prytkova M.Y. 1982. Geographic patterns of sedimentation in small reservoirs. Dr. Sc. Thesis. Leningrad. 477 p. [In Russian]
Shiklomanov I.A., Babkin V.I., Balonishnikov Z.A. 2011. Water resources, their use, and water availability in Russia: Current estimates and forecasts. Water Resources 38(2): 139–148. DOI: 10.1134/S009780781101012X
Syphard A.D., Garcia M.W. 2001. Human- and beaver-induced wetland changes in the Chickahominy River watershed from 1953 to 1994. Wetlands 21(3): 342–353. DOI: 10.1672/0277-5212(2001)021[0342:HABIWC]2.0.CO;2
Thompson S., Vehkaoja M., Pellikka J., Nummi P. 2020. Ecosystem services provided by beavers Castor spp. Mammal Review 51(1): 25–39. DOI: 10.1111/mam.12220
Vaughn C.C. 2010. Biodiversity losses and ecosystem function in freshwaters: emerging conclusions and research directions. BioScience 60(1): 25–35. DOI: 10.1525/bio.2010.60.1.7
Zavyalov N.A., Petrosyan V.G., Goryainova Z.I., Mishin A.S. 2016. On the interaction of beavers (Castor fiber, C. canadensis) and forest fires. In: Increasing the efficiency of use and reproduction of natural resources. Novgorod. P. 200–202. [In Russian]
Zhigulina E.V., Mikhno V.B. 2019. Regional features of the structural and dynamic organization and transformation of the valley-river landscapes of the Voronezh Region. Nature and Society: in Search of Harmony 5: 73–84. [In Russian]