A shallow lake in an agricultural landscape – water quality, nutrient loads, future management

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Abstract

Qualitative analyses of nitrogen and phosphorus loads reaching the lake ecosystem provide a basis for pollution control, which is of paramount importance in shallow lakes due to the rapid turn-over of matter and energy. The studies of both external and internal loading were conducted in Lake Łeknenskie, a very shallow, through-flow lake situated in Western Poland. Strong eutrophication is manifested in rich rush vegetation and a lack of submerged macrophytes as well as nitrogen and phosphorus concentrations (max 13.04 mg N dm−3 and 0.32 mg P dm−3, respectively). Constant domination of cyanobacteria in the phytoplankton community was noted in almost all seasons with a 98% share in summer, resulting in 20 cm water transparency and 223 μg dm−3 of chlorophyll-a. The zooplankton community was dominated by rotifers. The main source of nutrients was the River Nielba. Spatial external nutrient loading was 1.93 g P m−2 yr−1 and 77.55 g N m−2 yr−1. An even higher load of phosphorus was released from the bottom sediments, 2.18 g P m−2 yr−1. A comprehensive action plan is required, aiming at the reduction of both external and internal nutrient loading. A series of solutions regarding local environmental conditions should be applied in the lake catchment, including biogeochemical barriers, denitrification walls, artificial retention basins or wetlands, but most of all – improvement in the functioning of the wastewater treatment plant. Restoration is possible, however, protection measures reducing external loading should be undertaken prior to phosphorus inactivation in the water column and in the bottom sediments, supported by biological methods e.g. biomanipulation.

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  • Beaulieu M. Pick F. Gregory-Eaves I. 2013 Nutrients and water temperature are significant predictors of cyanobacterial biomass in a 1147 lakes data set Limnol. Oceanogr. 58(5): 1736–1746.

  • Bednarek A. Szklarek S. Zalewski M. 2014 Nitrogen pollution removal from areas of intensive farming-comparison of various denitrification biotechnologies Ecohydrol. Hydrobiol. 14(2): 132–141.

  • Burger D.F. Hamilton D.P. Pilditch C.A. 2008 Modelling the relative importance of internal and external nutrient loads o water column nutrient concentrations and phytoplankton biomass in a shallow polymictic lake Ecol. Modell. 211: 411–423.

  • Carlson R.E. 1977 A trophic state index for lakes Limnol. Oceanogr. 22(2): 361–369.

  • Celewicz-Gołdyn S. Klimko M. Kuczyńska-Kippen N. Nagengast B. 2010 Relationship between plankton assemblages and habitat characteristics of stands of Typha angustifolia and Chara hispida in Lake Wielkowiejskie Oceanol. Hydrobiol. Stud. 39(1): 127–135.

  • Choiński A. 2006 Katalog jezior Polski (The catalogue of Polish lakes) Wydaw. Nauk. UAM Poznań 600 pp (in Polish).

  • Dokulil M.T. Teubner K. 2003 Eutrophication and restoration of shallow lakes – the concept of stable equilibria revisited Hydrobiologia 506–509: 29–35.

  • Dondajewska R. Kozak A. Budzyńska A. Kowalczewska-Madura K. Gołdyn R. 2018 Nature-based solutions for protection and restoration of degraded Bielsko Lake Ecohydrol. Hydrobiol. 18(4): 401–411.

  • Dunalska J.A. Grochowska J. Wiśniewski G. Napiórkowska-Krzebietke A. 2015 Can we restore badly degrade urban lakes? Ecol. Eng. 82: 432–441.

  • Dunalska J.A. Napiórkowska-Krzebietke A. Ławniczak-Malińska A. Bogacka-Kapusta E. Wiśniewski G. 2018 Restoration of flow-through lakes – theory and practice Ecohydrol. Hydrobiol. 18(4): 379–390.

  • [EC] European Commission 2000 Directive 2000/60/EC of the European Parliament and of the Council of 23 October 2000 establishing a framework for Community action in the field of water policy Offic. J. Eur. Union L327 43: 1–72.

  • Ejsmont-Karabin J. 2012 The usefulness of zooplankton as lake ecosystem indicators: Rotifer Trophic State Index Pol. J. Ecol. 60: 339–350.

  • Elbanowska H. Siepak J. Zerbe J.1999 Fizyczno-chemiczne badania wody (Physico-chemical analyses of waters) Wydaw. Nauk. PWN Warszawa 236 pp (in Polish).

  • Finlay J.C Small G.E. Sterner R.W. 2013 Human influences on nitrogen removal in lakes Science 342: 247–250.

  • Forsberg C. 1989 Importance of sediments in understanding nutrient cyclings in lakes Hydrobiologia 176–177: 263–277

  • Fridrich B. Krčmar D. Dalmacija B. Malnar J. Pešić V. Kraguli M. Varga N. 2014 Impact of wastewater from pig farm lagoons on the quality of local groundwater Agric. Water Manage. 135: 40–53.

  • Gao C. Zhu J.G. Zhu J.Y. Gao X. Dou Y.J. Hosen Y. 2004 Nitrogen export from an agriculture watershed in the Taihu Lake area China Environ. Geochem. Hlth. 26: 199–207.

  • Gołdyn B. Kowalczewska-Madura K. Celewicz-Gołdyn S. 2015 Drought and deluge: Influence of environmental factors on water quality of kettle holes in two subsequent years with different precipitation Limnologica 54: 14–22.

  • Gołdyn R. Podsiadłowski S. Dondajewska R. Kozak A. 2014 The sustainable restoration of lakes – towards the challenges of the Water Framework Directive Ecohydrol. Hydrobiol. 14(1): 67–74.

  • Gržetić I. Čamprag N. 2010 The evolution of the trophic state of the Palić Lake (Serbia) J. Serb. Chem. Soc. 75: 717–732.

  • Ibelings B.W. Chorus I. 2007 Accumulation of cyanobacterial toxins in freshwater ‘seafood’ and its consequences for public health: a review Environ. Pollut. 150(1): 177–192.

  • Janssen A.B.G. de Jager V.C.L. Janse J.H. Kong X. Liu S. Ye Q. Mooij W.M. 2017 Spatial identification of critical nutrient loads of large shallow lakes: implications for Lake Taihu (China) Wat. Res. 119: 276–287.

  • Ji L. Berezina N.A. Golubkov S.M. Cao X. Golubkov M.S. Song C. Umnova L.P. Zhou Y. 2011 Phosphorus flux by macrobenthic invertebrates in a shallow eutrophic lake Donghu: spatial change Knowl. Managt. Aquatic Ecosyst. 402 11: 1–11.

  • Kokociński M. Mankiewicz-Boczek J. Jurczak T. Spoof L. Meriluoto J. Rejmonczyk E. Hautala H. Vehniäinen M. Pawełczyk J. Soininen J. 2013 Aphanizomenon gracile (Nostocales) a cylindrospermopsin-producing cyanobacterium in Polish lakes Environ. Sci. Pollut. Res. Int. 20(8): 5243–5264

  • Kowalczewska-Madura K. 2003 Mass balance calculations of nitrogen and phosphorus for Swarzędzkie Lake Limnol. Rev. 3: 113–118.

  • Kowalczewska-Madura K. Gołdyn R. 2009 The internal loading of phosphorus from the sediments of Swarzędzkie Lake (Western Poland) Pol. J. Environ. Stud. 18: 635–643.

  • Kowalczewska-Madura K. Dondajewska R. Gołdyn R. 2008 Influence of iron treatment on phosphorus internal loading from bottom sediments of the restored lake Limnol. Rev. 8: 177–182.

  • Kowalczewska-Madura K. Dondajewska R. Gołdyn R. 2011 Seasonal changes of phosphorus release from the bottom sediments of Rusałka Lake during the restoration process Ecol. Chem. Eng. A 18(2): 219–224.

  • Kowalczewska-Madura K. Gołdyn R. Dera M. 2014 Spatial and seasonal changes of phosphorus internal loading in two lakes with different trophy Ecol. Eng. 74: 187–195.

  • Lindim C. Becker A. Grüneberg B. Fischer H. 2015 Modelling the effects of nutrient loads reduction and testing the N and P control paradigm in a German shallow lake Ecol. Eng. 82: 415–427.

  • Ławniczak-Malińska A. Achtneberg K. 2018 On the use of macrophytes to maintain functionality of overgrown lowland lakes Ecol. Eng. 113: 52–60.

  • Łopata M. Czerniejewski P. Wiśiewski G. Czerniawski R. Drozdowski J. 2017 The use of expanded clay aggregate for the pretreatment of surface waters on the example of a tributary of Lake Klasztorne Górne in Strzelce Krajeńskie Limnol. Rev. 17(1): 3–9

  • Messyasz B. 2006 Chlorophyta – plants connected with diverse water reservoirs Biodiv. Res. Conserv. 3–4: 352–356.

  • Messyasz B. Nagengast B. 2000 Charakterystyka fitoplanktonu wody i roślinności Jeziora Łekneńskiego (Characteristics of phytoplankton and water and rush vegetation of Łeknenskie Lake) [in:] Wyrwa A.M. (ed.) Studia i materiały do dziejów Pałuk. Środowisko naturalne i osadnictwo w Łeknenskim kompleksie osadniczym. T. 3 (Studies and materials for the history of Pałuki Region. Environment and settlement in Łeknenski settlement complex. Vol. 3) Wydaw. Nauk. UAM Poznań: 25–36 (in Polish).

  • Mioduszewski W. 2012 Small water reservoirs – their function and construction J. Water Land Dev. 17(VII–XII): 45–52.

  • Moss B. Jeppesen E. Søndergaard M. Lauridsen T.L. Liu Z. 2013 Nitrogen macrophytes shallow lakes and nutrient limitation: resolution of a current controversy? Hydrobiologia 710(1): 3–21.

  • Myślińska E. 2001 Gleby organiczne i metody ich analizy laboratoryjnej (Organic soils and methods of analysis in laboratory) Wydaw. Nauk. PWN Warszawa 208 pp (in Polish).

  • Napiórkowska-Krzebietke A. Dunalska J. 2015 Phytoplankton-based recovery requirement for urban lakes in the implementation of the Water Framework Directive’s ecological targets Oceanol. Hydrobiol. Stud. 44(1): 109–119.

  • [OECD] Organisation for Economic Cooperation and Development 1982 Eutrophication of waters: monitoring assessment and control OECD Paris 154 pp.

  • Paerl H.W. Otten T.G. 2016 Duelling ‘CyanoHABs’: unravelling the environmental drivers controlling dominance and succession among diazotrophic and non-N2-fixing harmful cyanobacteria Environ. Microbiol. 18(2): 316–324

  • Psenner R. Boström B. Dinka M. Pettersson K. Pucsko R. Sager M. 1988 Fractionation of phosphorus in suspended matter and sediment Arch. Hydrobiol. Beih. Ergebn. Limnol. 30: 83–112.

  • Radwan S. Ejsmont-Karabin J. Bielańska-Grajner T. 2004 Część ogólna Monogononta – część systematyczna (General part Monogononta – taxonomical part) [in:] Radwan S. (ed.) Wrotki (Rotifera). Fauna słodkowodna Polski (Rotifera. Freshwater fauna of Poland) PTH Łódź: 1–146 (in Polish).

  • Reynolds C.S. Huszar V. Kruk C. Naselli-Flores L. Melo S. 2002 Towards a functional classification of the freshwater phytoplankton J. Plankton Res. 24: 417–428.

  • Rott E. 1981 Some results from phytoplankton counting intercalibrations Schweiz. Z. Hydrol. 43(1): 34–62.

  • Rybak J.I. Błędzki L.A. 2010 Słodkowodne skorupiaki planktonowe. Klucz do oznaczania gatunków (Freshwater planktonic crustaceans. The Key for species determination) Wydaw. UW Warszawa 366 pp (in Polish).

  • Scheffer M. 1998 Ecology of shallow lakes Chapman and Hall London 357 pp.

  • Søndergaard M. Jensen J.P. Jeppensen E. 2001 Retention and internal loading of phosphorus in shallow eutrophic lakes. Review Article Scien. World 1: 427–442.

  • Stefaniak K. Kokociński M. Messyasz B. 2005 Dynamics of Planktothrix agardhii (Gom.) Anagn. et Kom. blooms in polimictic Lake Laskownickie and Grylewskie (Wielkopolska region) Poland Oceanol. Hydrobiol. Stud. 34(Suppl. 3): 125–136.

  • Steinman A. Chu X. Ogdahl M. 2009 Spatial and temporal variability of internal and external phosphorus loads in Mona Lake Michigan Aquat. Ecol. 43: 1–18.

  • Szajdak L. Życzyńska-Bałoniak I. Jaskulska R. Szczepański M. 2009 Changes of the concentrations of dissolved chemical compounds migrating into ground water through biogeochemical barriers in an agricultural landscape Oceanol. Hydrobiol. Stud. 38(4): 109–116.

  • Szeszycki M. 2000 Jezioro Łekneńskie i jego ichtiologiczna charakterystyka (Łeknenskie Lake and its ichtiological characteristic) [in:] Wyrwa A.M. (ed.) Studia i materiały do dziejów Pałuk. Środowisko naturalne i osadnictwo w Łeknenskim kompleksie osadniczym. T. 3 (Studies and materials for the history of Pałuki Region. Environment and settlement in Łeknenski settlement complex. Vol. 3) Wydaw. Nauk. UAM Poznan: 14–23 (in Polish).

  • Świerk D. Szpakowska B. 2013 An ecosystem valuation method for small water bodies Ecol. Chem. Eng. S. 20(2): 397–418.

  • Triest L. Stiers I. van Onsem S. 2016 Biomanipulation as a nature-based solution to reduce cyanobacterial blooms Aquat. Ecol. 50(3): 461–483.

  • van Dam H. Martens A. Sinkeldam J. 1994 A coded checklist and ecological indicators values of freshwater diatoms from the Netherlands Neth. J. Aquat. Ecol. 28: 117–133.

  • Vollenweider R.A. 1976 Advances in defining critical loading levels for phosphorus in lake eutrophication Mem. Ist. Ital. Idrobiol. 33: 53–83.

  • Vymazal J. 2011 Plants used in constructed wetlands with horizontal subsurface flow: a review Hydrobiologia 674(1): 133–156.

  • von Elert E. 2004 Food quality constraints in Daphnia: interspecific differences in the response to the absence of a long chain polyunsaturated fatty acid in the food source Hydrobiologia 526: 187–196.

  • Wang J. Zhao Q. Pang Y. Hu K. 2017 Research on nutrient pollution in Lake Taihu China Environ. Sci. Pollut. Res. 24(21): 17829–17838.

  • Wejnerowski Ł. Cerbin S. Dziuba M. 2015 Thicker filaments of Aphanizomenon gracile are more harmful to Daphnia than thinner Cylindrospermopsis raciborskii Zool. Stud. 54(1): 1–13.

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