Phosphorus in sediments and pore waters of selected Polish dam reservoirs

• Autorzy: Trojanowska A. , Jezierski P.
• Języki publikacji: EN

Abstrakty

EN

This study aimed to examine and explain the spatial distribution of total phosphorus in sediments and orthophosphates in interstitial water in four Polish dam reservoirs with varying hydrological and geochemical characteristics. The results are linked to physicochemical parameters of sediments: organic matter and calcium carbonates content, pH, redox potential and conductivity. In two of the studied reservoirs hydrological dynamics were a driving force in phosphorus circulation, despite the big difference in their mean water retention times, and interactions with Ca and Fe were of secondary importance In other reservoirs with complicated shorelines and reservoir beds, due to water flow disturbance the hydrological impact was not as pronounced. Geochemical processes, such as precipitation of phosphorus associated with Ca^+2, Fe(III) or in complexed with humic substances became more significant.

Słowa kluczowe

EN

total phosphorus; phosphate; sediment(s); interstitial water; dam reservoirs

• Wydawca: Institute of Oceanography University of Gdańsk
• Czasopismo: Oceanological and Hydrobiological Studies
• Rocznik: 2011
• Tom: Vol. 40, No.2
• Strony: 72--85
• Opis fizyczny: Bibliogr. 51 poz., tab., wykr.

Twórcy

autor

Trojanowska A.

autor

Jezierski P.

• Laboratory of Isotope Geology and Geoecology Institute of Geological Sciences, University of Wroclaw ul. Cybulskiego 30, 50-205 Wroclaw, Poland,

Bibliografia

• 1.Ambrożewski Z., 1996, Ecological and flood problems of Sulejowski dam reservoir. Aura, 7: 19-21 (in Polish)
• 2.Bostrőm B., Andersen J.M., Fleischer S., Jansson M., 1988, Exchange of phosphorus across the sediment-water interface. Hydrobiologia, 170: 229-244.
• 3.Conley D.J., Johnstone R.W., 1995, Biogeochemistry of N, P and Si in Baltic Sea sediment: response to a simulated deposition of a spring diatom bloom, Mar. Ecol. Prog. Ser., 122: 265-276
• 4.Daessle L.W., Camacho-Ibar V.F., Carriquiry J.D., Ortiz-Hernandez M.C., 2004. The geochemistry and sources of metals and phosphorus in the recent sediments from the Northern Gulf of California. Continental Shelf Research 24. 2093-2106.
• 5.Dondajewska R., 2008, Internal phosphorus loading from bottom sediments of a shallow preliminary reservoir. Oceanological and Hydrobiological Studies, 37: 89-97
• 6.Drynda, R. 2010. The causes of variability of heavy metals concentration in bottom sediments of the Turawa reservoir. University of Wroclaw, master thesis pp.51 (in Polish)
• 7.Falkowski P.G., Raven, J.A. 1997. Carbon acquisition and assimilation. [In] Falkowski P.G., Raven, J.A. Aquatic photosynthesis. Blackwell Science, 129-193
• 8.Fox LE.A, 1989, Model for inorganic control of phosphate concentrations in river waters. Geochim Cosmochim Acta, 53: 417-41 8.
• 9.Gierszewski P., Szmanda J.B., 2006, Distribution of the bottom deposits and accumulation dynamics in the Wloclawek Reservoir (central Poland). Wseas Transaction on Environment and Development, 2: 543-549.
• 10.Gurwin J., Kryza J., Poprawki, L., Skowronek A., 2005, Geoecological studies of Turawa Lake. III-rd Cconference: Water resources of Terrasic in the Opole Region and Turawa Lakes, Strzelce Opolskie (in Polish)
• 11.Górniak A., 1995, Importance of humic acids as a factor affecting phytoplankton functioning. In: Zalewski M. (ed.). Biological processes In protection and recultivation of lowland dam reservoirs.. Biblioteka Monitoringu Środowiska, Łódź, 125-134 (in Polish)
• 12.Górniak A., Jekaterinczuk-Rudczyk E., 2006, Organic carbon in botton of Siemianowka reservoir. In: Górniak A., (ed.) Ekosystem of Siemianówka reservoir in 1990 - 2004 and its recultivation. Departament of Hydrobiology, Universitty in Białystok, 111-112 (in Polish).
• 13.Golterman H. L., Clymo R. S., and. Ohstand M. A. M., 1978, Methods for physical and chemical analysis of freshwater. Blackwell Scientific Publication, Londres, pp.214
• 14.Goltermann H. L., 1995, The role of the iron hydroxide phosphate-sulphide system in the phosphate exchange between sediments and overlying water. Hydrobiologia, 297: 43-54.
• 15.Graca B., Witek Z., Burska D., Białkowska I., Pawelec A., Bolałek J., 2006, Porewater nutrients (phosphate, ammonia and silicate) in the eastern part of the southern Baltic Sea. Oceanological and Hydrobiological Studies, 35: 237-256
• 16.Harper D., 1992, Eutrophication of freshwaters. Principles, problems and restoration. London, New York, Chapman and Hall, pp. 315
• 17.Håkanson L., Jansson M., 1983, Principles of lake sediemntology. Springer-Verlag, Berlin, Heidelberg, New York, Tokyo, pp. 316.
• 18.Håkanson L., 1995. Models to predict lake annual mean total phosphorus. J. Aquat. Ecol. Syst. Health, 4: 25-58.
• 19.House W.A, Denison F.H., 1998, Phosphorus dynamics in a lowland river. Water Res; 32::1819-1830
• 20.House W.A, Denison F.H., 2002, Total phosphorus content of river sediments in relationship to calcium, iron and organic matter concentrations. The Science of the Total Environment, 282-283: 341-351
• 21.Jezierski, P, Trojanowska, A., Kurasiewicz, M., Mejer T., Drynda R., 2009. The determinant sof heavy metals and arsenic concentrations in sediments of dam reservoirs Turawa and Włocławek [In:] Marszelewski W. (ed.) Antropogenic and natural transformations of lakes, PTLim Toruń. 3:109-115. (in Polish).
• 22.Kajak Z., 1995, Eutrophication of lowland dam reservoirs. [In:] Zalewski M. (ed.) Biological processes in protection and recultivation of lowland dam reservoirs, Biblioteka Monitoringu Środowiska, Łódź, pp. 33-41 (in Polish)
• 23.Kastelan-Macan M., Petrovic M., 1996. The role of fulvic acids in phosphorus sorption and release from mineral particles. Water Science and Technology, 34 (7-8). 259-265.
• 24.Koschel R, Benndorf J, Proft G, Rechnagel F., 1983, Calcite precipitation as a natural control mechanism of eutrophication. Arch Hydrobiol; 98: 380-408.
• 25.Kowalczewska-Madura K., Jeszke B., Furmanek S., Gołdyn R., 2005, Spatial and seasonal variation of phosphorus fractions in bottom sediments of the hypertrophic Swarzędzkie Lake (W Poland). Limnological Review 5: 123-128
• 26.Kuchler-Krischun J, Kleiner J. Heterogenously nucleated calcite precipitation: Lake Constance, a short resolution study. Aquatic Sci., 1990: 176-197.
• 27.Li Q.M., Zhang W., Wang X.X., ZhoU Y.Y., Yang H. and Ji G.L., 2007, Phosphorus in Interstitial Water Induced by Redox Potential in Sediment of Dianchi Lake, China. Pedosphere 17: 739 - 746
• 28.Łukawska-Matuszewska K., Bolałek J., 2008. Spatial distribution of phosphorus forms in sediments in the Gulf of Gdańsk (southern Baltic Sea), Continental Shelf Research 28. 977-990
• 29.Markel D., Kołodny Y., Luz B., Nishri A., 1994. Phosphorus cycling and phosphorus sources in Lake Kinneret: Tracing by oxygen isotopes in phosphate. Isr. J. Earth. Sci. 43:165-178
• 30.Matuszewska K., Białkowska I., Bolałek J., 2003, Interdependence between phosphorus forms in sediments and iron in interstitial waters in the Gulf of Gdańsk, Oceanological and Hydrobiological Studies, 32: 5-14
• 31.McManus J., Berelson W.M., Coale K.H., Johnson K.S., Kilgore T.E., 1997, Phosphorus regeneration in continental margin sediments. Geochimica et Cosmochimica Acta, 61: 2891-2907.
• 32.Murphy J. and Riley J. P., 1962, A modified single-solution method for the determination of phosphate in natural waters. Anal. Chim. Acta, 27: 31-36.
• 33.Müller G. and Heidelberg E.G., 1971, The "Karbonat-Bombe" a simle device for the determination of the carbonate content in sediments, soils and other materials. N.Jb.Miner.Mh., 10: 466-469.
• 34.Myślińska, E., 1992. Laboratory studies of grounds. Wydawnictwo Naukowe PWN, 54-57. (in Polish)
• 35.Nielsen T., Andersen F., 2003. Phosphorus dynamics during decomposition of mangrove (Rhizophora apiculata) leaves in sediments. Journal of Experimental Marine Biology and Ecology 293 (2003) 73- 88
• 36.Pacini, N., Harper, D.M., Ittekott, V., Humborg, C. & Rahm L. 2008, Nutrient Processes and consequences. In: Harper, D.M., Zalewski M., Pacini N. (eds.) Ecohydrology. Processes, models and case studies, CABI, 30-45.
• 37.Psenner R., Pucsko R., 1988, Phosphorus fractionation: limits and correlations. Archiv of Hydrobiologie, 30: 43-59.
• 38.Reddy KR, Kadlec RH, Flaig E, Gale PM. 1999, Phosphorus retention in streams and wetlands: a review. Crit Rev Environ Sci Technol, 29: 83-146.
• 39.Simeonov, V., Massart D.L., Andreev G. and Tsakovski S., 2000. Assessment of metal pollution based on multivariate statistical modeling of "hot spot" sediments from the Black sea. Chemosphere, 41: 1411-1417.
• 40.Simeonov V., Wolska L., Kuczyńska A., Gurwin J., Tsakovski S., Protasowicki M., Namieśnik J., 2007. Sediment-quality assessment by intelligent data analysis. Trends in Analytical Chemistry, 26: 323-331.
• 41.Søndergaard M., Jensen J.P. and Jeppesen E., 2003, Role of sediment and internal loading of phosphorus in shallow lakes. Hydrobiologia, 506-509: 135-145.
• 42.Suchowolec, T., 2006, Morphology and technical aspects of Siemianówka reservoir. In: Górniak A., (red.) Ecosystem of the Siemianówka reservoir in 1990-2004 and its recultivation. Zakład Hydrobiologii Uniwersytetu w Białymstoku, 22-26. (in Polish)
• 43.Suchowolec T., Górniak A.,, 2009. Riverine water transformation during retention in small lowland reservoirs. Oceanological and Hydrobiological Studies, 38: 103-108
• 44.Swenson, R. M., C. V. Cole & D. H. Sieling, 1949, Fixation of phosphate by iron and aluminum and inorganic ions. Soil Sci., 67: 3-22.
• 45.Tiessen H. 1995, Introduction and synthesis. In: Tiessen H, editor. SCOPE 54 Phosphorus in the global environment, transfers, cycles and management. Chichester: John Wiley and Sons, 1-6.
• 46.Trojanowska A., Izydorczyk K., 2010, Phosphorus fractions transformation in sediments before and after cyanobacterial bloom: implications for reduction of eutrophication symptoms in dam reservoir. Water air and Soil Pollution. (DOI 10.1007/s11270-009-0299-y)
• 47.Tuominen L., Mäkelä K., Lehtonen Haahti K.K., Hietanen H., Kuparinen J., 1999, Nutrient fluxes, porewater profiles and denitrification in sediment influenced by algal sedimentation and bioturbation by Monoporeia affinis, Estuarine and Coastal Shelf Science, 49: 83-97
• 48.Verrhiest, G.J., Clement B., Volat B., Montuelle B., Perrodon Y., 2002, Interactions between a polycyclic aromatic hydrocarbon mixture and the microbial communities in a natural freshwater sediment. Chemosphere, 46: 187-196.
• 49.Wang S., Jin X., Zhań H., Zhou X., Wu Z., 2008, Effects of organic matter on phosphorus release kinetics in different rophic lake sediments and application of transition state theory. Journal of Environmental Management, 88: 845-852
• 50.Wiśniewski R. J., 1995, The role of internal loading in eutrophication of dam reservoirs. In: Zalewski M. (ed.) Biological proces in protection and recultivation of lowland dam reservoirs. Biblioteka Monitoringu Środowiska, Łódź, 61-70 (in Polish)
• 51.Zalewski, M.,. Wagner-Lotkowska I. and Tarczyńska M., 2000, Ecohydrological approaches to the elimination of toxic algal blooms in the a lowland reservoir. Verh. Int. Ver. Theor. Angew. Limnol., 27: 3176-3183.