Drip irrigation of vegetable crops
- Авторлар: Fedosov A.Y.1, Menshikh A.M1, Yanchenko A.V1, Ivanova M.I1, Eremenko A.N2
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Мекемелер:
- ARRIVG – a branch of FSCV
- New Century Agritechnology Co Ltd.
- Шығарылым: № 4 (2025)
- Беттер: 31-37
- Бөлім: Vegetable growing
- URL: https://ogarev-online.ru/0022-9148/article/view/357466
- DOI: https://doi.org/10.25630/PAV.2025.56.30.005
- ID: 357466
Дәйексөз келтіру
Толық мәтін
Аннотация
The shortage of freshwater resources is a global problem, which is aggravated by the world's population growth and climate change caused by global warming. Despite the significant reserves of water resources that Russia has, a number of regions of the country are experiencing a deficit. Uneven distribution of runoff and precipitation by seasons of the year, as well as from year to year, is especially noticeable in arid regions of the country. To solve this problem, the vegetable sector of water consumption has adopted a number of measures called drip irrigation schemes. In Russia, drip irrigation equipment is mainly used for commercial crops such as fruit and vegetable crops. The main goals of drip irrigation are to reduce water deficit near the root zone, reduce evaporation and reduce water consumption. The scope of application of drip irrigation is becoming wider. The effects of drip irrigation technology on plant growth and development, quality, yield, and water use efficiency are summarized. An overview of drip irrigation technology on root development and nitrogen uptake in vegetable crops is presented. Drip irrigation technology is effective in improving vegetable crop growth, increasing water use efficiency, and reducing water stress, as well as reducing fertilizer leaching and soil salinity, making it an ideal solution to address the global shortage of freshwater. Despite the numerous advantages of drip irrigation technology, high initial installation and maintenance costs, variable water quality, limited technical knowledge and implementation support, and institutional barriers such as water management policies and regulations have limited its widespread adoption in vegetable production.
Негізгі сөздер
Авторлар туралы
A. Fedosov
ARRIVG – a branch of FSCV
A. Menshikh
ARRIVG – a branch of FSCV
A. Yanchenko
ARRIVG – a branch of FSCV
M. Ivanova
ARRIVG – a branch of FSCV
A. Eremenko
New Century Agritechnology Co Ltd.
Әдебиет тізімі
«Полюс»: водный отчет. Использование водных ресурсов и водохозяйственная деятельность [Электронный ресурс]. URL: https://sustainability.polyus.com/upload/files/sustainability-approach/POLYUS_WATER_REPORT_RUS.pdf Дата обращения: 20.06.2025. Инновационные технологии орошения овощных культур / А.Ю. Федосов, А.М. Меньших, М.И. Иванова, А.А. Рубцов. М. Изд-во Ким Л.А. 2021. 306 с. Федосов А.Ю., Меньших А.М., Иванова М.И. Дефицитное орошение овощных культур // Овощи России. 2022. № 3. С. 44–49. https://doi.org/10.18619/2072-9146-2022-3-44-49 Принципы управления орошением овощных культур. В.А. Фартуков, М.И. Зборовская, А.Ю. Федосов, А.М. Меньших, Д.М. Васильев. Инновации и инвестиции. 2022. №11. С. 262–268. Review on Drip Irrigation: Impact on Crop Yield, Quality, and Water Productivity in China. P. Yang, L. Wu, M. Cheng, J. Fan, S. Li, H. Wang, L. Qian. Water. 2023. № 15. Р. 1733. Интеллектуальная система полива: цифровые решения в овощеводстве / А.М. Меньших, А.Ю. Федосов, В.А. Янченко, В.А. Фартуков, М.И. Иванова // Рисоводство. 2024. Т. 23. № 2 (63). С. 76–84. Star ruby” grapefruit and “Clemenules” mandarin trees show different physiological and agronomic responses to irrigation with saline water / J.G. Pérez-Pérez, F. García-Sánchez, J. M. Robles, P. Botía. Irrig. Sci. 2015. № 33. Рр. 191–204. Ecofert: An android application for the optimization of fertilizer cost in fertigation. M.V. Bueno-Delgado, J.M. Molina-Martínez, R. Correoso-Campillo, P. Pavón-Mariño. Comput. Electron. Agric. 2016. № 121. Рр. 32–42. Assessment of field water budget components for increasing water productivity under drip irrigation in arid and semi-arid areas, Syria. B.A. Zakhem, F. Al Ain, R. Hafez. Irrig. Drain. 2019 № 68. Рр. 452–463. Jia B., Fu J. Critical nitrogen dilution curve of drip-irrigated maize at vegetative growth stage based on leaf area index. Trans. Chin. Soc. Agric. Eng. 2020. № 36. Рр. 66–73. Ayars J., Fulton А., Taylor В. Subsurface drip irrigation in California-Here to Stay? Agric. Water Manag. 2015. № 157. Рр. 39–47. Effects of nitrogen application and aerated irrigation on soil environment and yield in cucumber root area. B. Cui; W. Niu; Y. Du; Q. Zhang. Water Sav Irrig. 2020. №4. Pp. 27–32. Effects of different water and fertilization on nutrient uptake, yield and quality of greenhouse muskmelon under drip irrigation condition. W. Yue; W. He; C. Ding; Y. Bai, Y. Zhou; H. Xi. Acta Agric. Zhejiangensis. 2021. №33. Pp. 2370–2380. Luo, H.; Li, F. Water and nitrogen coupling effects and model under tomato drip irrigation. Chin. Agric. Sci. Bull. 2022. № 38. Pp. 30–36. Lian, X.; Wang, Y.; Liang, X.; Li, H.; Wang, Z. Effects of irrigation methods on yield, quality and economic benefit of green radish by sowing seed tape. Tianjin Agric. Sci. 2021. № 27. Pp. 53–56. Effects of drip irrigation patterns and biochar amendment on green pepper yield, quality and soil nitrogen transformational enzyme activities in greenhouse. H. Qiu; W. Zhang; J. Liu, M. Lv; Y. Wang. China Soils Fert. 2022. No9. Pp. 67–74. Impacts of oxygation on plant growth, yield and fruit quality of tomato. Y. Zhu; H. Cai; L. Song; H. Chen. Trans. Chin. Soc. Agric. Mach. 2017. №48. Pp. 199–211. Магомедова Д.С., Курбанов С.А. Сравнительная эффективность возделывания томатов при капельном орошении и поливе по бороздам // Орошаемое земледелие. 2022. № 1 (36). С. 40–43. Павленко В.Н. Зайцев В.А. Применение удобрений при выращивании лука на капельном орошении // Орошаемое земледелие. 2024. № 1(44). С. 21–25. Бабичев А.Н., Рубцов А.А., Бабенко А.А. Влияние минерального питания на урожайность лука репчатого // Пути повышения эффективности орошаемого земледелия (Материалы конференции). 2020. № 4(80). С. 141–144. Ирков И.И., Успенская О.Н., Берназ Н.И. Эффективность распределённого внесения азота на луке репчатом (Allium cepa L.) в однолетней культуре // Овощи России. 2023. № 3. С. 88–92. https://doi.org/10.18619/2072-9146-2023-3-88-92 Mahajan G.; Singh K. Response of greenhouse tomato to irrigation and fertigation. Agric. Water Manag. 2006. №84. Pp. 202–206. Spatial distribution of added selenium in soil as affected by different irrigations using reclaimed water. T. Ma; F. Gao; C. Liu; C. Hu; B. Cui; E. Cui; Y. Hao. J. Irrig. Drain. 2022. №41. Pp. 58–64. Effects of different fertilization levels on greenhouse tomato under aerated irrigation. W. Yang, F. Liu; T. Liu; D. Wang, Q. Zhang. Water Sav Irrig. 2019. №7. Pp. 49–55. Effect of airjection irrigation on growth and yield of mini-watermelon in greenhouse. J. Liu, H. Cai, M. Zhang; X. Chen; J. Wang. Water Sav. Irrig. 2010. №24. Pp. 24–27. Effects of different irrigation methods and fertilizer amount on wheat yield and utilization of water, fertilizer and medicine. D. Tian; C. Hou; J. Ren; L. Hao; Z. Li. Water Sav. Irrig. 2022. №10. Pp. 100–104. Modeling nitrogen transport and leaching process in a greenhouse vegetable filed. H. Lei; G. Li; W. Ding, C. Xu, H. Wang; H. Li. Chin. J. Eco Agric. 2021. №29. Pp. 38–52. Effects of irrigation and fertilization on nutrient absorption and yield of cucumber and soil quality in greenhouse. Y. Tang, L. Li, P. Liu; G. Bai. China Soils Fert. 2018. №1. Pp. 77–82. Zhang Z.; Zhao W.; Li J. Effects of drip irrigation frequency and nitrogen fertilizer on nitrate leaching and tomato growth. J. China Inst. Water Res. Hydropower Res. 2015. №13. Pp. 81–90. Дорджиев С.А. Автоматизация систем капельного полива // Картофель и овощи. 2022. №6. С. 3–4.
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