Analysis of urbanization impact on changes in river discharge - a case study of the Biała River catchment

• Autorzy: Chormański J.
• Języki publikacji: EN

Abstrakty

EN

The article presents a simulation of urbanization impact on runoff changes in an urbanized catchment. Application of a distributed hydrological WetSpa model enabled comprehensive use of Landsat satellite images as a source of data about contemporary and historical land cover in the catchment. The analyses conducted for the Biała river catchment, with over 60% of the area being urbanized, revealed a significant influence of changes in the size of urbanized area on runoff hydrograph.

Słowa kluczowe

EN

WetSpa; Landsat data; urbanization; river discharge; river basin; hydrological model; river catchment

PL

urbanizacja; wypływ rzeki; zlewnia rzeki; model hydrologiczny; WetSpa; Landsat

• Wydawca: De Gruyter
• Czasopismo: Studia Geotechnica et Mechanica
• Rocznik: 2012
• Tom: Vol. 34, nr 2
• Strony: 19--32
• Opis fizyczny: Bibliogr. 30 poz., tab., rys., wykr.

Twórcy

autor

Chormański J.

• Department of Hydraulic Engineering, Warsaw University of Life Sciences, Nowoursynowska 166, 02-787 Warsaw,

Bibliografia

• [1] ALLEN R.G., PEREIRA L.S., RAES D., SMITH M., Crop Evapotranspiration. Guidelines for Computing Crop Water Requirements, Vol. 56, Food and Agriculture Organization of the United Nations, 1998.
• [2] BATELAAN O., WANG Z.M., De SMEDT F., An adaptive GIS toolbox for hydrological modeling, [in:] K. Kovar, H.P. Nachtnebel, (eds.), Application of geographic information systems in hydrology and water resources management, IAHS Publ., No. 235, 1996.
• [3] BEREZOWSKI T., CHORMAŃSKI J., BATELAAN O., CANTERS F., Van De VOORDE T., Impact of remotely sensed land-cover proportions on urban runoff prediction, International Journal of Applied Earth Observation and Geoinformation, 2012, 16, 54–65.
• [4] CHORMAŃSKI J., BATELAAN O., Application of the WetSpa distributed hydrological model for catchment with significant contribution of organic soil. Upper Biebrza case study, Annals of Warsaw University of Life Sciences, SGGW Land Reclamation, 2011, 43(1), 25–35.
• [5] CHORMAŃSKI J., MICHAŁOWSKI R., Model hydrologiczny zlewni Wet-Spa zintegrowany z modułem obliczeniowym w środowisku ArcGIS, Przegląd Naukowy Inżynieria i Kształtowanie Środowiska, 2011, Vol. 20(3), 196–206
• [6] CHORMAŃSKI J., PUSŁOWSKA-TYSZEWSKA D., KARDEL I., MIROSŁAW-ŚWIĄTEK D., OKRUSZKO T., Model zlewni o parametrach przestrzennych dyskretnie rozłożonych w obszarze zurbanizowanym, Przegląd Naukowy Inżynieria i Kształtowanie Środowiska, 2012, Vol. 21, Issue 1(55), 3–17.
• [7] CHORMAŃSKI J., Van De VOORDE T., De ROECK T., BATELAAN O., CANTERS F., Improving Distributed Runoff Prediction in Urbanized Catchments with Remote Sensing based Estimates of Impervious Surface Cover, Sensors, 2008, 8, 910–932
• [8] CRUISE J.F., LAYMON C.A., AL-HAMDAN O.Z., Impact of 20 Years of Land-Cover Change on the Hydrology of Streams in the Southeastern United States, Journal of the American Water Resources Association, 2010, 46, 1159–1170.
• [9] DOHERTY J., BREBBER L., WHYTE P., PEST: model independent parameter estimation. User manual, Watermark Computing Trademarks, Australia, 1994.
• [10] GEIGER W., DREISEITL H., Nowe sposoby odprowadzania wód deszczowych, Oficyna Wyd. ProjprzemEKO, Bydgoszcz 1999.
• [11] GUS, 2011, Baza Danych Głównego Urzędu Statystycznego, stan na rok 2011, http://www.stat.gov.pl/gus
• [12] GUTRY-KORYCKA M., Urbanization in the global change development syndrome, Global Change, 2005, 12, 7–21.
• [13] GUTRY-KORYCKA M., Odpływ ze zlewni zurbanizowanych, Prace i Studia Geograficzne, 2007, 38, 37–56.
• [14] KAZUBSKI O., Wpływ urbanizacji na zmiany odpływu w zlewni rzeki Białej, manuskrypt pracy magisterskiej, SGGW, Warszawa 2011.
• [15] LIU Y.B., GEBREMESKEL S., De SMEDT F., PFISTER L., Flood prediction with the WetSpa model on a catchment scale, [in:] B.S. Wu, Z.Y. Wang, G.Q. Wang, G.H. Huang, H.W. Fang, J.C. Huang, (eds.), Flood Defence, Science Press, New York 2002.
• [16] LIU Y.B., Development and application of a GIS-based hydrological model for flood prediction and watershed management, Vrije Universiteit Brussel Press, Brussel, 2004, 315.
• [17] MARTINE G., The State of the World Population 2007. United Nation Population Fund, New York 2007.
• [18] NASA Landsat Program, 1972–2011: ETM+, TM, MSS scenes, USGS, Sioux Falls.
• [19] NASH J., SUTCLIFFE J., River flow forecasting through conceptual models, Part 1. A discussion of principles, J. Hydrol., 1970, 10, 282–290.
• [20] OLANG L.O., FÜRST J., Effects of land cover change on flood peak discharges and runoff volumes: model estimates for the Nyando River Basin, Kenya, Hydrol. Process, 2010, 25, 80–89.
• [21] OLANG L., KUNDU P., BAUER T., FÜRST J., Analysis of spatio-temporal land cover changes for hydrological impact assessment within the Nyando River Basin of Kenya, Environmental Monitoring and Assessment, 2011, 179, 389–401
• [22] PORRETTA-BRANDYK L., CHORMAŃSKI J., IGNAR S., OKRUSZKO T., BRANDYK A., SZYMCZAK T., KRĘŻAŁEK K., Evaluation and verification of the WetSpa model based on selected rural catchments in Poland, J. Water and Land Development, 2010, 14, 115–133.
• [23] PORRETTA-BRANDYK L., CHORMAŃSKI J., OKRUSZKO T., BRANDYK A., Automatic calibration of the WetSpa distributed hydrological model for small lowland catchments, [in:] M. Świątek, T. Okruszko (eds.), Modelling of Hydrological Processes in the Narew Catchment, Geoplanet: Earth and Planetary Sciences, Springer-Verlag, Berlin, Heidelberg, 2011, 43–62.
• [24] De SMEDT F., LIU Y.B., GEBREMESKEL S., Hydrologic modeling on a catchment scale using GIS and remote sensed land use information, [in:] Risk Analysis II, C.A. Brebbia (ed.), WTI Press, Southampton, Boston, 2000, 295–304.
• [25] TOURBIER J.T., WESTMACOTT R., Water resources protection technology, US EPA, 1981.
• [26] TYSZEWSKI S., KARDEL I., PUSŁOWSKA-TYSZEWSKA D., OKRUSZKO T., STAŃCZYK T., OGLECKI P., CHORMAŃSKI J., MIROSŁAW-ŚWIĄTEK D., MICHAŁOWSKI R., POLAK W., Studium hydrograficzne doliny rzeki Białej z wytycznymi do zagospodarowania rekreacyjno-wypoczynkowego i elementami małej retencji oraz prace hydrologiczne niezbędne do sporządzenia dokumentacji hydrologicznej, Warszawa 2009.
• [27] WANG Z.M., BATELAAN O., De SMEDT F., A distributed model for water and energy transfer between soil, plants and atmosphere (WetSpa), Phys. Chem. Earth, 1996, 21(3), 189–193.
• [28] WITTENBERG H., SIVAPALAN M., Watershed groundwater balance estimation using streamflow recession analysis and baseflow separation, J. Hydrol., 1999, 219, 20–33.
• [29] ZHANG S., NA X., KONG B., WANG Z., JIANG H., YU H., ZHAO Z., LI X., LIU C., DALE P., Identifying Wetland Change in China's Sanjiang Plain Using Remote Sensing Wetlands, Wetlands, 2009, 29, 302–313.
• [30] http://lwf.ncdc.noaa.gov/oa/ncdc.html