Powiadomienia systemowe
- Sesja wygasła!
Tytuł artykułu
Autorzy
Treść / Zawartość
Pełne teksty:
Identyfikatory
Warianty tytułu
Języki publikacji
Abstrakty
The urbanisation and suburbanisation processes are considered to have a detrimental impact on the environment. Increasing the share of the impervious surfaces is one of their main negative effects, particularly in and near the cities, affecting the water relations of basins. It also results in new catchment boundaries formation and, in many cases, changes in the physiographic parameters affecting the accuracy of hydrological and hydraulic calculations of small suburban catchments. This study is an attempt to delimit the catchment boundaries located in the suburban area of Poznań city, Poland, in three variants: according to the Raster Hydrographical Map of Poland and Raster Topographical Map of Poland, digital elevation model, and rainwater sewage system. The analyses were conducted with ArcGIS software, and the results were additionally verified with geodesic measurements on site. This work focuses mainly on the impact of anthropogenic pressure on the catchment shape and the course of its boundaries. The analyses were conducted on the Rów WB stream catchment located in the Skórzewo village, Dopiewo municipality, which stands out within the Poznań Metropolitan Area as the area where the suburbanisation process is the most intensified. This study proved that the agrotechnical and drainage works performed in undeveloped, agricultural areas affected catchment shape and size as much as suburbanisation itself. According to the authors, the suburban catchment boundaries should be regularly updated due to the intensity of the new investments development and additionally verified on site.
Słowa kluczowe
Czasopismo
Rocznik
Tom
Strony
202--208
Opis fizyczny
Bibliogr. 26 poz., rys., tab.
Twórcy
autor
- Institute of Land Improvement, Environmental Development and Geodesy, Poznań University of Life Sciences, ul. Wojska Polskiego 28, 60-637, Poznań, Poland
autor
- Institute of Land Improvement, Environmental Development and Geodesy, Poznań University of Life Sciences, ul. Wojska Polskiego 28, 60-637, Poznań, Poland
autor
- Institute of Land Improvement, Environmental Development and Geodesy, Poznań University of Life Sciences, ul. Wojska Polskiego 28, 60-637, Poznań, Poland
Bibliografia
- 1. Borowiak K., Lisiak M., Kanclerz J., Budka A., Mleczek M., Niedzielski P., Adamska A., Janicka E. 2018. Relations between rare earth elements accumulation in Taraxacum officinale L. and land use in an urban area – A preliminary study. Ecological Indicators, 94, 22–27.
- 2. Di Giulio M., Holderegger R., Tobias S. 2009. Effects of habitat and landscape fragmentation on humans and biodiversity in densely populated landscapes. Journal of environmental management, 90(10), 2959–2968.
- 3. Gudowicz J., Zwoliński Z. 2017. Shaping of river outflow in the Parsęta basin in the light of hydrological modelling. Przegląd Geograficzny, 89(1), 45–66 (in Polish).
- 4. Hawley R. J., Bledsoe B. P. 2011. How do flow peaks and durations change in suburbanizing semiarid watersheds? A southern California case study. Journal of Hydrology, 405(1–2), 69–82.
- 5. Kanclerz J., Borowiak K., Mleczek M., Staniszewski R., Lisiak M., Janicka E. 2016. Cadmium and Lead Accumulation in Water and Macrophytes in an Artificial Lake. Annual Set The Environment Protection, 18(1), 322–336.
- 6. Kim H. W., Li M. H., Kim J. H., Jaber F. 2016. Examining the Impact of Suburbanization on Surface Runoff using the SWAT. International Journal of Environmental Research, 10(3), 379–390.
- 7. Liu S., Xia X., Yang L., Shen M., Liu R. 2010. Polycyclic aromatic hydrocarbons in urban soils of different land uses in Beijing, China: distribution, sources and their correlation with the city’s urbanization history. Journal of Hazardous Materials, 177(1–3), 1085–1092.
- 8. Mrozik K., Przybyła Cz., Pyszny K. 2015. Problems of the Integrated Urban Water Management. The Case of the Poznań Metropolitan Area (Poland). Annual Set The Environment Protection, 17, 230–245.
- 9. Mrozik K. 2016. Assessment of retention potential changes as an element of suburbanisation monitoring on example of an ungauged catchment in Poznań Metropolitan Area (Poland). Annual Set The Environment Protection, 18(1), 188–200.
- 10. Mrozik K., Idczak P. 2015. The suburbanisation in selected rural communes of Bydgoszcz-Toruń Metropolitan Area. Studies and Works of the Faculty of Economics and Management, 42(2), 183–194 (in Polish).
- 11. National Water Management Authority. 2005. Raster Hydrographical Map of Poland 1:50 000.
- 12. Podawca K, Karsznia K., Pawłat-Zawrzykraj A. 2019. The assessment of the suburbanisation degree of Warsaw Functional Area using changes of the land development structure. Miscellanea Geographica, Vol. 23, nr 4, s. 215–224.
- 13. Podawca K., Mrozik K. 2019. Diversifying of the degree of implementation of planning and investment processes in the communes of the Warsaw Functional Urban Area. Scientific Review. Engineering and Environmental Sciences, Vol. 28 (1), nr 83, s. 105–117 (in Polish).
- 14. Podawca K., Pawłat-Zawrzykraj A. 2017. Social and infrastructural conditions of the rural area development in the Tarczyn municipality with respect to location of housing areas. Acta Scientiarum Polonorum. Formatio Circumiectus, nr 16 (2), s. 15–31(in Polish).
- 15. Przybyła Cz., Bykowski J., Mrozik K., Napierała M. 2011. The role of water and drainage system infrastructure in the process of suburbanization. Annual Set The Environment Protection, 13, 769–786 (in Polish).
- 16. Scolozzi R., Geneletti D. 2012. A multi-scale qualitative approach to assess the impact of urbanization on natural habitats and their connectivity. Environmental Impact Assessment Review, 36, 9–22.
- 17. Simon E., Braun M., Vidic A., Bogyó D., Fábián I., Tóthmérész B. 2011. Air pollution assessment based on elemental concentration of leaves tissue and foliage dust along an urbanization gradient in Vienna. Environmental pollution, 159(5), 1229–1233.
- 18. Sojka M., Jaskuła J., Wielgosz I. 2017. Drought risk assessment in the Kopel River Basin. Journal of Ecological Engineering, 18(6), 134–141.
- 19. Su S., Xiao R., Jiang Z., Zhang Y. 2012. Characterizing landscape pattern and ecosystem service value changes for urbanization impacts at an eco-regional scale. Applied Geography, 34, 295–305.
- 20. Tefera A. H. 2017. Characterization of Beles River Basin of Blue Nile sub-Basin in North-Western Ethiopia using Arc-Hydro tools in Arc-GIS. International Journal of Water Resources and Environmental Engineering, 9(5), 113–120.
- 21. Urbański J. 2012. GIS in environmental studies. University of Gdańsk, Gdańsk (online, in Polish).
- 22. Venticinque E., Forsberg B., Barthem R., Petry P., Hess L., Mercado A., Cañas C., Montoya M., Durigan C., Goulding M. 2016. An explicit GISbased river basin framework for aquatic ecosystem conservation in the Amazon. Earth System Science Data, 8(2), 651–661.
- 23. Voivodeship Inspectorate for Environmental Protection in Poznań. 2016. Report on the classification of water quality indicators in the Wielkopolska voivodeship for 2016. Wirynka – Łęczyca (online, in Polish).
- 24. Walek G. 2017. The use of GIS mmethods in urban catchment drainage divides delineation on example of the Kielce city. Przegląd Naukowy. Inżynieria i Kształtowanie Środowiska, 26(3), 326–335 (in Polish).
- 25. Yang J. L., Zhang G. L. 2011. Water infiltration in urban soils and its effects on the quantity and quality of runoff. Journal of soils and sediments, 11(5), 751–761.
- 26. Zhao P. 2010. Sustainable urban expansion and transportation in a growing megacity: Consequences of urban sprawl for mobility on the urban fringe of Beijing. Habitat International, 34(2), 236–243.
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-1f5461a7-5281-415a-a0c8-ffeb794f584e