Water Needs of the Ash-Leaved Maple (Acer negundo L.) at the Period over Three Years after Reclamation in Different Regions of Poland

Rolbiecki, Stanisław; Rolbiecki, Roman; Jagosz, Barbara; Kasperska-Wołowicz, Wiesława; Ptach, Wiesław; Stachowski, Piotr; Figas, Anna; Grybauskiene, Vilda; Klimek, Andrzej; Podsiadło, Cezary

doi:10.12911/22998993/102790

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Tytuł artykułu

Water Needs of the Ash-Leaved Maple (Acer negundo L.) at the Period over Three Years after Reclamation in Different Regions of Poland

Autorzy

Rolbiecki Stanisław , Rolbiecki Roman , Jagosz Barbara , Kasperska-Wołowicz Wiesława , Ptach Wiesław , Stachowski Piotr , Figas Anna , Grybauskiene Vilda , Klimek Andrzej , Podsiadło Cezary

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10_Rolbiecki_i in._Water Needs_4_2019.pdf

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DOI

10.12911/22998993/102790

Warianty tytułu

Języki publikacji

Abstrakty

The ash-leaved maple (Acer negundo L.) has low habitat requirements, which is why this species is often used in the reclamation of industrial areas. The development of the reclamation plantings depends on the optimal water soil conditions that can be controlled by watering treatments. However, the use of irrigation requires determining the water needs of the cultivated species. The objective of the study was to evaluate the water needs of the ash-leaved maple in the reclamation plantings, in the period of over three years after planting. The water needs of the ash-leaved maple were determined using the crop coefficients method. Potential evapotranspiration was calculated using the Blaney-Criddle’s formula that was modified for the Polish conditions by Żakowicz. The water needs of the ash-leaved maple were assessed for five agro-climatic regions of Poland, in the years 1981-2010. The water needs of the ash-leaved maple in the growing period (April-October) were the highest in the C-E (638 mm) and C-N-W (637 mm) regions, and the lowest in the N-E (598 mm) and S-E (601 mm) regions. In July, the highest water needs were noted in the C-N-W region (149 mm) and the lowest in the S-W region (129 mm). In the studied thirty-years period, there was a significant upward trend in the water needs of the ash-leaved maple both during the growing season (except for the C-N-W region) and in July, in all the considered regions.

Słowa kluczowe

irrigation potential evapotranspiration rainfall deficiencies water requirements

Wydawca

Polskie Towarzystwo Inżynierii Ekologicznej
Lublin University of Technology

Czasopismo

Journal of Ecological Engineering

Rocznik

2019

Tom

Vol. 20, nr 4

Strony

69--75

Opis fizyczny

Bibliogr. 26 poz., rys., tab.

Twórcy

autor

Rolbiecki Stanisław

rolbs@utp.edu.pl

Department of Agrometeorology, Plant Irrigation and Horticulture, University of Science and Technology in Bydgoszcz, Bernardyńska 6, 85-029 Bydgoszcz, Poland

autor

Rolbiecki Roman

rolbr@utp.edu.pl

Department of Agrometeorology, Plant Irrigation and Horticulture, University of Science and Technology in Bydgoszcz, Bernardyńska 6, 85-029 Bydgoszcz, Poland

autor

Jagosz Barbara

Institute of Plant Biology and Biotechnology, University of Agriculture in Krakow, 29 Listopada 54, 31-425 Krakow, Poland

autor

Kasperska-Wołowicz Wiesława

Institute of Technology and Life Sciences in Falenty, Kuyavian-Pomeranian Research Centre, Glinki 60, 85-174 Bydgoszcz, Poland

autor

Ptach Wiesław

Department of Engineering and Geodesy, Warsaw University of Life Sciences, Nowoursynowska 159, 02-776 Warszawa, Poland

autor

Stachowski Piotr

Poznań University of Life Sciences, Faculty of Environmental Engineering and Spatial Management, Institute of Land Improvement, Environmental Development and Geodesy, Piątkowska 94, 60-649 Poznań, Poland

autor

Figas Anna

Department of Plant Genetics, Physiology and Biotechnology, University of Science and Technology in Bydgoszcz, Bernardyńska 6, 85-029 Bydgoszcz, Poland

autor

Grybauskiene Vilda

Institute of Water Resources Management, Aleksandras Stulginskis University in Kaunas, Studentu g. 10, Lithuania

autor

Klimek Andrzej

Department of Zoology and Landscaping, University of Science and Technology, Kordeckiego 20, 85-225 Bydgoszcz, Poland

autor

Podsiadło Cezary

Department of Plant Production and Irrigation, West Pomeranian University of Technology in Szczecin, Słowackiego 17, 71-430 Szczecin, Poland

Bibliografia

1. Biniak-Pieróg M., Żyromski A., Rolbiecki R., Rolbiecki S., Żyromski M. and Żmuda R. 2016. Effect of thermal conditions and precipitation on growth rate of Scots pine. Journal of Ecological Engineering, 17(5), 1-8.
2. Cerny T.A., Kuhns M., Kopp K.L. and Johnson M. 2002. Efficient irrigation of trees and shrubs. Utah State University Cooperative Extension, 1-5.
3. Danielewicz W. and Wiatrowska B. 2014. The most invasive tree and shrub species in Polish forests. Peckiana, 9, 59-67. (in Polish)
4. Frączek J., Mudryk K. and Wróbel M. 2009. Ashleaved maple Acer negundo L. – the new potential energy species. Acta Agrophysica, 14(2), 313-322. (in Polish)
5. Klimek A., Rolbiecki S., Rolbiecki R., Hilszczańska D. and Malczyk P. 2011. Effects of organic fertilization and mulching under micro-sprinkler irrigation on growth and mycorrhizal colonization of European larch seedlings, and occurrence of soil mites. Polish Journal of Environmental Studies, 5(20), 1211-1219.
6. Klimek A., Rolbiecki S., Rolbiecki R., Długosz J. and Musiał M. 2013. The use of compost from sewage sludge and forest ectohumus for enrichment of soils in the nursery cultivation of littleleaf linden (Tilia cordata Mill.). Annual Set The Environment Protection, 15, 2811-2828.
7. Kuchar L., Iwański S., Diakowska E. and Gąsiorek E. 2015. Simulation of hydrothermal conditions for crop production purpose until 2050-2060 and selected climate change scenarios for North Central Poland. Infrastructure and Ecology of Rural Areas II(1), 319-334.
8. Kuchar L., Iwański S., Diakowska E. and Gąsiorek E. 2017. Assessment of meteorological drought in 2015 for North Central part of Poland using hydrothermal coefficient (HTC) in the context of climate change. Infrastructure and Ecology of Rural Areas, I(2), 257-273.
9. Łabędzki L. 2009. Foreseen climate changes and irrigation development in Poland. Infrastructure and Ecology of Rural Areas, 3, 7-18.
10. Łabędzki L., Bąk B. and Liszewska M. 2013. Impact of climate change on water demand of late potato. Infrastructure and Ecology of Rural Areas, 2(I), 155-165. (in Polish)
11. Pacewicz K., Wróbel M., Wieczorek T., Gilewska M. and Otremba K. 2006. Growth characteristics of Acer negundo, Eleagnus angustifolius and Robinia pseudoacacia trees on wet ash disposal site. Acta Scientarium Polonarum, Formatio Circumiectus 5(1), 87-98. (in Polish)
12. Ptach W., Łangowski A., Rolbiecki R., Rolbiecki S., Jagosz B., Grybauskiene V. and Kokoszewski M. 2017. The influence of irrigation on the growth of paulownia trees at the first year of cultivation in a light soil. Proc. 8th International Scientific Conference Rural Development 2017, 764-768.
13. Ranney T.G., Whitlow T.H. and Bassuk N.L. 1990. Response of five temperate deciduous tree species to water stress. Tree Physiology, 6, 439-448.
14. Roberts B.R. and Schnipke V.M. 1987. Water requirements of five container-grown Acer species. Journal of Environmental Horticulture, 5(4), 173175.
15. Rolbiecki S., Rolbiecki R., Rzekanowski Cz., Żarski J. 2000. The influence of sprinkler irrigation on yields of some vegetable crops in the region of Bydgoszcz, Poland. Acta Horticulturae, 537, 871877.
16. Rolbiecki S., Kokoszewski M., Grybauskiene V., Rolbiecki R., Jagosz B., Ptach W. and Łangowski A. 2017. Effect of expected climate changes on the water needs of forest nursery in the region of central Poland. Proc. 8th International Scientific Conference Rural Development 2017, 786-792.
17. Rzekanowski C., Pierzgalski E. 2006. Irrigation of forest nurseries. In: S. Karczmarczyk and L. Nowak (Eds). Plant irrigation. PWRiL, Poznań, 194-197.
18. Sjöman H., Hirons A.D. and Bassuk N.L. 2015. Urban forest resilience through tree selection Variation in drought tolerance in Acer. Urban Forestry & Urban Greening, 14, 858-865.
19. Stachowski P. 2009. Purposefulness of spray irrigation during agricultural cultivation of postmining grounds. Annual Set of Environment Protection, 11, 1131-1142.
20. Stachowski P. and Markiewicz J. 2011. The need of irrigation in central Poland on the example of Kutno county. Annual Set of Environment Protection, 13, 1453-1472.
21. White J.C. and Smith W.K. 2013. Water sources in riparian trees of the southern Appalachian foothills, U.S.A.: A preliminary study with stable isotope analysis. Riparian Ecology and Conservation, 1, 46-52.
22. White J.C. and Smith W.K. 2015. Seasonal variation in water sources of the riparian tree species Acer negundo and Betula nigra, southern Appalachian foothills, USA. Botany, 93, 519-528.
23. Żakowicz S. 2010. Principles of irrigation technology of restoration municipal wastes landfills. Ed. SGGW, Treatises and Monographs, 1-95. (in Polish)
24. Żakowicz S., Hewelke P., Gnatowski T. 2009. Basics of technical infrastructure in the agricultural space. Ed. SGGW. Warszawa, 1-192. (in Polish)
25. Żakowicz S., Hewelke P. 2012. Plant irrigation technology on restoration municipal wastes landfills. Ed. SGGW, Warszawa, 1-155. (in Polish)
26. Żarski J., Dudek S., Kuśmierek-Tomaszewska R., Rolbiecki R. and Rolbiecki S. 2013. Forecasting effects of plants irrigation based on selected meteorological and agricultural drought indices. Annual Set The Environment Protection, 15, 2185-2203.

Uwagi

Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2019).

Typ dokumentu

Bibliografia

Identyfikator YADDA

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