سامانه پشتیبانی خدمات اطلاعات

  اخبار و اعلانات

 آمار

تعداد نشریات161
تعداد شماره‌ها6,532
تعداد مقالات70,501
تعداد مشاهده مقاله124,099,482
تعداد دریافت فایل اصل مقاله97,206,951
احمدی مرادی, مبینا, سعیدی نیا, مهری, نصرالهی, علی حیدر, شریفی پور, مجید. (1402). ارزیابی برهم‌کنش سطوح مختلف آبیاری و کود نیتروژن بر عملکرد ذرت علوفه‌ای در خرم‌آباد. , 13(4), 1019-1034. doi: 10.22059/jwim.2023.359093.1075
مبینا احمدی مرادی; مهری سعیدی نیا; علی حیدر نصرالهی; مجید شریفی پور. "ارزیابی برهم‌کنش سطوح مختلف آبیاری و کود نیتروژن بر عملکرد ذرت علوفه‌ای در خرم‌آباد". , 13, 4, 1402, 1019-1034. doi: 10.22059/jwim.2023.359093.1075
احمدی مرادی, مبینا, سعیدی نیا, مهری, نصرالهی, علی حیدر, شریفی پور, مجید. (1402). 'ارزیابی برهم‌کنش سطوح مختلف آبیاری و کود نیتروژن بر عملکرد ذرت علوفه‌ای در خرم‌آباد', , 13(4), pp. 1019-1034. doi: 10.22059/jwim.2023.359093.1075
احمدی مرادی, مبینا, سعیدی نیا, مهری, نصرالهی, علی حیدر, شریفی پور, مجید. ارزیابی برهم‌کنش سطوح مختلف آبیاری و کود نیتروژن بر عملکرد ذرت علوفه‌ای در خرم‌آباد. , 1402; 13(4): 1019-1034. doi: 10.22059/jwim.2023.359093.1075

ارزیابی برهم‌کنش سطوح مختلف آبیاری و کود نیتروژن بر عملکرد ذرت علوفه‌ای در خرم‌آباد

مدیریت آب و آبیاری
دوره 13، شماره 4، دی 1402، صفحه 1019-1034    اصل مقاله (737.64 K)
نوع مقاله: مقاله پژوهشی
شناسه دیجیتال (DOI): 10.22059/jwim.2023.359093.1075
نویسندگان
مبینا احمدی مرادی؛ مهری سعیدی نیا* ؛ علی حیدر نصرالهی؛ مجید شریفی پور
گروه مهندسی آب، دانشکده کشاورزی، دانشگاه لرستان، لرستان، ایران.
چکیده
این پژوهش به‌منظور بررسی برهم­کنش سطوح مختلف آبیاری و کود نیتروژن بر عملکرد ذرت علوفه­ای در شهرستان خرم­آباد انجام گرفت. طرح آزمایشی به‌صورت فاکتوریل بر پایه بلوک­های کامل تصادفی با احتساب اولین فاکتور شامل چهار سطح 125، 100، 75 و 50 درصد نیاز آبی (I125، I100، I75 و I50 ) و دومین فاکتور شامل سه سطح کود نیتروژن 100، 250 و 400 کیلوگرم در هکتار (N100، N250 و N400) در سه تکرار اجرا گردید. براساس روش تشت تبخیر، مجموع عمق آب آبیاری برای تیمارهای I125، I100، I75 و I50 در طول دوره به‌ترتیب 761، 642، 524 و 406 میلی‌متر برآورد گردید که بیش‌تر از میزان نیاز آبی گزارش‌شده در سند ملی نیاز آبی گیاهان می­باشد. نتایج نشان داد بیش‌ترین میزان عملکرد ماده تر و خشک، شاخص سطح برگ و ارتفاع گیاه، در تیمار I125N400  ،به‌ترتیب با مقادیر 80 و  2/21 تن در هکتار، 9595 میلی‌متر مربع و220 سانتی‌متر به‌دست آمد که نسبت به تیمار شاهد (I100N250)  در سطح معنی‌داری پنج درصد، افزایش داشتند. کم‌ترین مقدار این صفات به‌ترتیب برابر 30 و  64/10 تن در هکتار، 133/7096 میلی‌مترمربع، 100 سانتی‌متر در تیمار I50N400 به‌دست آمد که نسبت به تیمار شاهد (I100N250) در سطح معنی‌داری 5 درصد، کاهش را نشان دادند. براساس نتایج به‌دست‌آمده، در سطوح آبیاری 125 و 100 درصد، افزایش میزان کود مصرفی نسبت به تیمار شاهد، باعث افزایش معنی‌دار (سطح 5 درصد) عملکرد تر و شاخص سطح برگ گردید. در سطوح آبیاری 75 و 50 درصد نیاز آبی، افزایش میزان کود باعث تغییرات معنی‌داری در صفات اندازه‌گیری نشدند. در این پژوهش، بیش‌ترین میزان بهره‌وری آب برای  ماده تر و خشک در تیمار I100N400، به‌ترتیب 9/10 و 91/2 کیلوگرم بر مترمکعب به‌دست آمد.
کلیدواژه‌ها
بهره‌وری آب آبیاری؛ ذرت علوفه‌ای؛ کم‌آبیاری؛ کود نیتروژن
عنوان مقاله [English]
Investigating the Interaction of Different Irrigation and Nitrogen Fertilizer Levels on The Yield of Forage Corn in Khorramabad
نویسندگان [English]
mobina ahmadimoradi؛ Mehri Saeidinia؛ aliheidar nasrolahi؛ majid sharifipour
Department of Water Engineering, Faculty of Agriculture, Lorestan University, Lorestan, Iran.
چکیده [English]
This research was conducted in order to investigate the interaction of different levels of irrigation and nitrogen fertilizer on the yield of Forage Corn in Khorramabad. The experiment was conducted as factorial in a randomized complete block design with three replications. The first factor consisted of four irrigation levels including I125 (125 Percent of water requirement), I100 (100 Percent of water requirement), I75 (75 Percent of water requirement), and I50 (50 Percent of water requirement) and the second factor consisted of three levels of nitrogen fertilizer including N400 (400 Kg/ha), N250 (250 Kg/ha), and N100 (100 Kg/ha). Based on the evaporation pan method, the total irrigation requirement for treatments I125, I100, I75 and I50 during the period were 761, 642, 524 and 406 mm, respectively, which were more than the amount of water requirement reported in the national water requirement document of plants.The result showed that the maximum amount of wet and dry matters, plant height, leaf area index which were 80 and 21.2 tons per hectare, 9595 mm2 and 220 cm, respectively, were obtained in I125N400 treatment, which had a significant increase (5 Percent) compared to the control treatment (I100N250). The minimum amount of these traits which were 30 and 10.64 tons per hectare, 7096.133 mm2 and 100 cm, respectively, were obtained in I50N400 treatment, which had a significant decrease (5 Percent) compared to the control treatment (I100N250). It was found from the results of this research that at the levels of I125 and I100, the values of wet matter and leaf area index were increased as the amount of nitrogen fertilizer increased. At irrigation levels of 75 Percent and 50 Percent of water requirement, increasing the amount of fertilizer did not cause significant changes in the measured traits. In this research, the maximum value of water productivity for wet and dry matters was obtained in I100N400 treatment with values of 10.9 and 2.91 kg/m3, respectively. 
کلیدواژه‌ها [English]
Deficit Irrigation, Forage Corn, Irrigation Water Productivity, Nitrogen Fertilizer
مراجع
  1. Afrasiab, P., Delbari, M., & Jafari, H. (2016). Effect of different levels of irrigation, planting density, Planting pattern in drip irrigation on yield, yield components and water use efficiency of corn. Iranian Journal of Soil and Water Research, 47(4), 731-741. (In Persian)
  2. Agricultural statistics. (2018). Crops, water and soil, tools. Publications of the Ministry of Jihad and Agriculture, Vice President of Planning and Economy, Bureau of Statistics and Information Technology. (In Persian)
  3. Ahmadvand, M., Sharifipour, M., & Nasrollahi, A. (2021). Effect of Regulated Deficit Irrigation and Alternate Furrow Irrigation on Water Productivity of Forage Maize in Khorramabad Climatic. Irrigation Sciences and Engineering, 44(3), 129-143. (In Persian)
  4. Alizadeh, A. (2004). Soil Water- Plant Relationship. Iran, Imam Reza press. (In Persian)
  5. Ali Zadeh, H. A., & Abbasi, F. (2017). Assessment of AquaCrop Model for Simulating Yield Response of Corn to Water and Fertility Stresses. Irrigation Sciences and Engineering, 40(2), 119-134.
  6. Amanullah, H., Marwat, K. B., Shah, P., Maula, N., & Arifullah, S. (2009). Nitrogen levels and its time of application influence leaf area, height and biomass of maize planted at low and high density. J. Bot, 41(2), 761-768.
  7. Amerian, M., Hashemi Garmdareh, S. E., & Karami, A. (2021). Effect of Deficit Drip Irrigation on Yield and Water Use Efficiency of Single Cross Corn 704. Journal of Water Research in Agriculture, 35(3), 247-258.
  8. Amiri, A. (2017). Investigating the effect of irrigation frequency and nitrogen fertilizer amounts on some growth and yield indicators of corn. scientific-research journal of plant ecophysiology, 10(34), 59-71. (In Persian)
  9. Amiri, e., (2018). 'Investigation of irrigation interval and nitrogen rates on some growth indices and yield of corn', Journal of Plant Ecophysiology, 10(34), 59-71. (In Persian)
  10. Azizian, A., & Sepaskhah, A. R. (2014). Maize response to different water, salinity and nitrogen levels: agronomic behavior. International Journal of Plant Production, 8(1), 107-130.
  11. Chachar, A. N., Mirjat, M. U., Soothar, R. K., Shaikh, I. A., Mirjat, M. H., & Dahri, S. A. (2020). Effects of irrigation frequencies on soil salinity and crop water productivity of fodder maize. Acta Ecologica Sinica, 40(4), 277-282.
  12. Djaman, K., O’neill, M., Owen, C. K., Smeal, D., Koudahe, K., West, M., ... & Irmak, S. (2018). Crop evapotranspiration, irrigation water requirement and water productivity of maize from meteorological data under semiarid climate. Water, 10(4), 405.
  13. Evans, J. R. (1989). Photosynthesis and nitrogen relationships in leaves of C3 plants. Oecologia, 78(1), 9-19.
  14. Fang, H., Gu, X., Jiang, T., Yang, J., Li, Y., Huang, P., ... & Yang, J. (2020). An optimized model for simulating grain-filling of maize and regulating nitrogen application rates under different film mulching and nitrogen fertilizer regimes on the Loess Plateau, China. Soil and Tillage Research, 199, 104546.
  15. Farooq, M., Wahid, A., Kobayashi, N. S. M. A., Fujita, D. B. S. M. A., & Basra, S. M. A. (2009). Plant drought stress: effects, mechanisms and management. Sustainable agriculture, 153-188.
  16. Gheysari, M., Sadeghi, S. H., Loescher, H. W., Amiri, S., Zareian, M. J., Majidi, M. M., ... & Payero, J. O. (2017). Comparison of deficit irrigation management strategies on root, plant growth and biomass productivity of silage maize. Agricultural Water Management, 182, 126-138.
  17. Ghobadi, R., Shirkhani, A., & Jalilian, A. (2015). Investigating the effects of drought stress and nitrogen fertilizer on the yield and water use efficiency and nitrogen of corn plants (Sc 704). Journal of agriculture, 106, 79-87. (In Persian)
  18. Heydaripour, R., Mahallati, M. N., Koocheki, A., & Abadi, A. Z. F. (2014). The effects of different levels of irrigation and nitrogen fertilizer on productivity and efficiency in corn (Zea mays), sugar beet (Beta vulgaris L.) and sesame (Sesamum indicum L.). Journal of Agroecology, 6(2), 406.
  19. Shao, H. B., Chu, L. Y., Jaleel, C. A., & Zhao, C. X. (2008). Water-deficit stress-induced anatomical changes in higher plants. Comptes rendus biologies, 331(3), 215-225.
  20. Karimi, M., Esfahani, M., Biglouei, M. H., Rabiei, B., & Kafi, G. A. (2009). Effect of deficit irrigation treatments on morphological traits and growth indices of corn forage in the Rasht Climate. (In Persian)
  21. Kiani, M. (2011). Calibration and evaluation of OILCROP-SUN model for sunflower plant at different levels of applied water and nitrogen fertilizer. Master's thesis in irrigation and drainage, Faculty of Agriculture, Isfahan University of Technology. (In Persian)
  22. Kiani, M., Gheysari, M., Mostafazadeh-Fard, B., Majidi, M. M., Karchani, K., & Hoogenboom, G. (2016). Effect of the interaction of water and nitrogen on sunflower under drip irrigation in an arid region. Agricultural water management, 171, 162-172.
  23. Lalvand, P., Nasrolahi, A. H., Khorramian, M., & Saeidinia, M. (2020). Evaluation of CWSI for Three of Corn Cultivars under Drip Irrigation Regimes (The Lands of Khuzestan Northern). Journal of Water and Soil Resources Conservation, 9(4), 57-70. (In Persian)
  24. Majidian, M., Qalvand, A., KamgarHaghighi, A. A., & Karimian, N. (2008). The effect of drought stress, chemical nitrogen fertilizer and organic fertilizer on chlorophyll meter reading, grain yield and yield components of Single Cross 704 corn grains. Iranian Journal of Agricultural Sciences, 10(3), 303-330. (In Persian)
  25. Pourebrahimi, M., Siroosmehr, A., Eshghizadeh, H., Asgharipoor, M., & Khomri, A. (2016). The effect of different levels of nitrogen fertilizer on the yield and agronomic characteristics of different corn hybrids (Zea mays). Production and processing of agricultural and garden products, (3)8, 37-49. (In Persian)
  26. Rajabi, A. B. A. Z. A. R., Griffiths, H., & Ober, E. S. (2007). Relationship of carbon stable isotopes with water use efficiency in sugar beet under well-watered and drought conditions. Journal of Sugar Beet, 23(1), 12-1.
  27. Ramezanimoghaddam, G., Houshmand, A., Naseri, A., Mesgarbash, M., & Azizimobser, G. (2017). The effect of different amounts of irrigation and nitrogen fertilizer with the presence of underground water on spring corn yield. Water and soil knowledge, 27 (1), 229-251. (In Persian)
  28. Rodrigues, M. A., Pereira, A., Cabanas, J. E., Dias, L., Pires, J., & Arrobas, M. (2006). Crops use-efficiency of nitrogen from manures permitted in organic farming. European journal of agronomy, 25(4), 328-335.
  29. Sadraddini, A., Parandin, M., & Nazemi, A. H. (2019). Effects of Deficit Irrigation on Yield and Yield Components and Determination of Water Productivity of Zea Maize in Islamabad-Gharb Area. Journal of Water Research in Agriculture, 33(2), 189-204. (In Persian)
  30. Salvagiotti, F., Castellarín, J. M., Miralles, D. J., & Pedrol, H. M. (2009). Sulfur fertilization improves nitrogen use efficiency in wheat by increasing nitrogen uptake. Field Crops Research, 113(2), 170-177.
  31. Samdvand, S., Tajbakhsh, M., Anvari, K., & Ahmadali, J. (2013). The effect of drip irrigation systems in one and two row cultivation on the yield and water use efficiency of grain corn. Agricultural and natural resources sciences and techniques, water and soil sciences, 18 (4), 113-120. (In Persian)
  32. Sampathkumar, T., Pandian, B. J., Rangaswamy, M. V., Manickasundaram, P., & Jeyakumar, P. (2013). Influence of deficit irrigation on growth, yield and yield parameters of cotton–maize cropping sequence. Agricultural Water Management, 130, 90-102.
  33. Sepaskhah, A., Tavakoli, S., & Mousavi, F. (2011). The principles and application of deficit irrigation. publications of the National Irrigation and Drainage Committee of Iran. (In Persian)
  34. Shahrokhnia, M. (2012). Investigating the effect of using irrigation planning tools on the yield and water consumption of corn in two soil textures. Irrigation and drainage of Iran, sixth year, (4), 331-341. (In Persian)
  35. Sharief, A. E., & Keshta, M.M. (2006). Influence of sowing date and plant density on growth and yield of canola (Brassica napus) under salt affected soils in Egypt’s. Scientific Journal of King Faisal University (Basic and Applied Sciences), 3(1), 65-78.
  36. Shiferaw, B., Prasanna, B. M., Hellin, J., & Bänziger, M. (2011). Crops that feed the world 6. Past successes and future challenges to the role played by maize in global food security. Food security, 3, 307-327.
  37. Tabatabai, M. S., Qaysari, M., AbediKopaei, J., & Amiri, Z. (2017). The mutual effect of water and nitrogen on the yield and water use efficiency of irrigation water of fodder corn under drip-strip irrigation management. Journal of Irrigation and Drainage of Iran, 12(6), 1529-1539. (In Persian)
  38. Turgut, I., Duman, A., Wietgrefe, G. W., & Acikgoz, E. (2006). Effect of seeding rate and nitrogen fertilization on proso millet under dryland and irrigated conditions. Journal of plant nutrition, 29(12), 2119-2129.
  39. Wang, Y., Zhang, X., Chen, J., Chen, A., Wang, L., Guo, X., ... & Gao, Q. (2019). Reducing basal nitrogen rate to improve maize seedling growth, water and nitrogen use efficiencies under drought stress by optimizing root morphology and distribution. Agricultural Water Management, 212, 328-337.
  40. Yaseen, R., Shafi, J., Ahmad, W., Rana, M. S., Salim, M., & Qaisrani, S. A. (2014). Effect of deficit irrigation and mulch on soil physical properties, growth and yield of maize. Ecol. Res, 2(3), 122-137.
  41. Zhang, H., Yu, X., Jin, Z., Zheng, W., Zhai, B., & Li, Z. (2017). Improving grain yield and water use efficiency of winter wheat through a combination of manure and chemical nitrogen fertilizer on the Loess plateau, China. Journal of soil science and plant nutrition, 17(2), 461-474.
آمار
تعداد مشاهده مقاله: 142
تعداد دریافت فایل اصل مقاله: 111


سامانه مدیریت نشریات علمی. قدرت گرفته از سیناوب