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Formation of a Favorable Filtration Regime of Soils in Saline Areas of the Danube Delta Rice Irrigation Systems

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
The environmental state of rice irrigation systems (RIS) is determined by many factors, including natural ones (soil, topographical, hydrogeological, and climatic factors) and technological ones (irrigation norm, design, and parameters of irrigation and drainage networks, etc). The most significant influence on the ecological reclamation state of the RIS carries is effected by its drainage network (DN). The need to maintain a flushing water regime with specific filtration rates to prevent secondary salinization in the Danube Delta’s rice systems is a crucial aspect of managing these agricultural areas. In the saline areas of rice systems located in the Danube Delta, the DN must ensure the maintenance of the flushing water regime with the rates of filtration ranging between 10 to 12 mm/day. This is a prerequisite for preventing secondary salinization of irrigated lands of these rice systems. According to the results of studies, the filtration from the surface of the irrigation checks of the Danube Delta RIS has been established, and its values in the area of the rice check vary significantly. Different intensity of filtration in the area of rice checks causes the difference in mineralization of groundwater and in the content of salts in the soil. This leads to the fact that the same rice check created various natural reclamation conditions and different productivity of cultivated crops.
Rocznik
Strony
115--128
Opis fizyczny
Bibliogr. 30 poz., rys., tab., wykr.
Twórcy
  • National University of Water and Environmental Engineering, 11 Soborna Str., 33028, Rivne, Ukraine
  • National University of Water and Environmental Engineering, 11 Soborna Str., 33028, Rivne, Ukraine
  • Institute of Water Problems and Land Reclamation of the National Academy of Agrarian Sciences of Ukraine; 37 Vasylkivska Str., 03022, Kyiv, Ukraine
autor
  • National University of Water and Environmental Engineering, 11 Soborna Str., 33028, Rivne, Ukraine
  • National University of Water and Environmental Engineering, 11 Soborna Str., 33028, Rivne, Ukraine
Bibliografia
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  • Goncharov S. M. (1969) On the formation of the groundwater regime in rice irrigation systems of the central part of the Danube Delta, Reclamation and Water Management, 10, 37–44.
  • Fang R. J., Li Y. H., Zhang, M. Z. (1996) Study on growing features of rice roots under water deficyt irrigation conditions, China Rural Water and Hydropower, 8, 11–14.
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  • Kuzmych L., Voropay G., Moleshcha N., Babitska O. (2021) Improving Water Supply Capacity of Drainage Systems at Humid Areas in the Changing Climate, Archives of Hydro-Engineering and Environmental Mechanics, 68 (1), 29–40, https://doi.org/10.1515/heem-2021-0003.
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  • Li Y. H. (1999) Theory and techniques of water saving irrigation, Wuhan: Wuhan Uni. Of Hydraul. Electric Eng. Press, 310 p.
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  • Mendus S. P., Mendus P. I., Rokochynskyi A. M. (2007) Evaluation of the reclamation state and effectiveness of rice systems, Hydromelioration and hydrotechnical construction: coll. of science Works – Rivne, Issue 32, 38–49.
  • Monaco F., Sali G. (2018) How water amounts and management options drive IrrigationWater Productivity of rice. A multivariate analysis based on field experiment data, Agricultural Water Management, 195, 47–57.
  • Oliynyk O. Ya. (1981) Methodical recommendations for designing drainage on rice irrigation systems: recommendations, K.: Ministry of Vodkhoz of the Ukrainian SSR, 135 p.
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  • Prykhodko N., Koptyuk R., Kuzmych L., Kuzmych A. (2923) Formation and Predictive Assessment of Drained Lands Water Regime of Ukraine Polesie Zone, [In:] Handbook of Research on Improving the Natural and Ecological Conditions of the Polesie Zone, IGI Global of Timely Knowledge, Hershey, Pennsylvania 17033-1240, USA, 51–74, DOI: 10.4018/978-1-6684-8248-3.ch004.
  • Reuben P., Kahimba F. C., Katambara Z., Mahoo H. F., MbunguW., Mhenga F., Nyarubamba A., Maugo M. (2016) Optimizing Plant Spacing under the Systems of Rice Intensification (SRI), Agricultural Sciences, 7, 270–278. doi: 10.4236/as.2016.74026.
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  • Rokochinsky A. M., Turchenyuk V. O., Zayets V. V., Prykhodko N. V. (2014) Increasing the efficiency of the operation of Danube rice irrigation systems, Bulletin of Agrarian Science, Kyiv, 4 (734), 53–57.
  • Rokochynskyi A., Turcheniuk V., Zaiets V., Prykhodko N. (2015) Improving of water regulation technology and normalization of water and energy use at Danubian RIS on ecological and economic, principles taking into account the climate change, Proceedings of the III International Academic Congress “Problems and Prospects of Research in the Americas and Eurasia”, Buenos Aires, Argentina, 3–5 December 2014, Volume I, Buenos Aires University Press, Buenos Aires, 452–457.
  • Rokochinskiy A. M., Mendus P. I., Mendus S. P., Turchenyk V. A. (2016) Enhancing environment al safety rice systems, International Journal of New Economics and Social Sciences, 2 (4), 120–125.
  • Stashuk V. A., Rokochinsky A.M., Mendus P. I., Turchenyuk V. O. (2016) Rice of the Danube Delta Region, collective monograph, Kherson, Grin D.S., 620 p.
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  • Turchenuk V., Rokochinskiy A., Prykhodko N., Mendus S., Zaiets V. (2016) The efficiency of Danube rice irrigation systems drainage and ways of its improvement, The scientific heritage, 4 (4), 102–105.
  • Turchenuk V., Frolenkova N., Rokochynskyi A. (2017) Environmental and economic foundations of system optimization of operational, technological and construction parameters of rice irrigation systems, Environmental Economics, 8 (2), 76–82.
  • Turcheniuk V., Rokochinskiy A., Kuzmych L., Volk P., Koptyuk R., Romanyuk I., Voropay G. (2022) The efficiency of waste hot water utilization to improve the temperature conditions for growing plants, Journal of Water and Land Development, 54, 1–7, DOI: 10.24425/jwld.2022.141559.
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  • Zhovtonog N. I. (1984) The calculation of water filtration rates on rice checks, Land Reclamation and Water Management, 61, 7–11.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-4e2b2afb-7bcb-40d3-b5d0-738513c8d7ed
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