Effect of Nitrogen Fertilizer and Irrigation Levels on Yield and Some Physiological Traits of Wheat under Drip Irrigation

Document Type : Research Article

Authors

1 Department of Agronomy and Plant Breeding, Faculty of Agriculture, University of Kurdistan, Sanandaj, Iran

2 Department of Water Science and Engineering, Faculty of Agriculture, University of Kurdistan, Sanandaj, Iran

Abstract

Introduction
Wheat is globally one of the most critical cereals. It is necessary to increase its yield to cope with the increasing population through management improvement or breeding due to decreased arable lands. Soil moisture before planting and rainfall during the growing season are the two primary water supply sources for rainfed wheat production. However, the non-uniform distribution of rainfall during the growing season leads to drought, affecting crop water consumption and natural wheat growth. Irrigation is the primary way to meet the plant's water requirement for growth, development, and high yield. Since water availability is limited in Iran and on the other hand, different cultivars have different sensitivities to drought stress at various stages of growth, so reducing different degrees of water consumption may have unequal effects on crop yield. This type of management, known as deficit-irrigation, often increases water use efficiency. Drip irrigation provides optimized use of water and nutrients during the growing season. In addition to water consumption, the balanced application of fertilizers is an influential factor in increasing agricultural production, and nitrogen is the most critical fertilizer recommended to improve wheat yield. Nitrogen can increase wheat yield by increasing the number of spikes per square meter, the number of grains per spike, and 1000-grain weight. This study aims to determine the optimum water consumption and nitrogen fertilizer under the drip irrigation system according to wheat physiological traits.
Materials and Methods
This experiment was performed as split plot based on a randomized complete block design with three replications in the Research Farm of the University of Kurdistan located in the Dehgolan plain in 2018-19 cropping year. Factors were in various irrigation levels (60, 80, 100, and 120% of crop water requirement) as the main plots and nitrogen fertilizer treatments (fertilizer application of 50, 75, 100, and 125% of plant nitrogen requirement based on soil test) as subplots. Sampling was done in all three replications to calculate soil weight moisture and determine the irrigation water requirement in each irrigation stage. The soil moisture balance method was used to determine the crop's water requirement according to the volume percentage of moisture in the control plot (treatment of providing 100% water requirement). Based on the soil test results, the optimal nitrogen application in the control treatment was considered equivalent to 200 kg.ha-1 of urea. Other experimental treatments were calculated based on the control treatment. In this experiment, traits such as biological yield, grain yield, harvest index, water use efficiency (WUE), chlorophyll content (chlorophyll a, chlorophyll b, and total chlorophyll), remobilization, grain protein content, protein percent, and agronomic nitrogen use efficiency (ANUE) were evaluated. Data were analyzed using SAS statistical software, and the means were compared using Duncan's multiple range test at 5% probability.
Results and Discussion
The results showed that the effects of different irrigation and nitrogen levels were significant on biological yield, grain yield (P <0.01), and grain protein percent (p≤0.05). The interaction effect of irrigation and nitrogen was significant on WUE (p≤0.05), chlorophyll content, remobilization, and ANUE (P <0.01). In comparing different irrigation levels, The highest and lowest biological yields were obtained in the treatments of 120% water requirement (15976 kg.ha-1) and 60% water requirement (12975 kg.ha-1), respectively. Among different nitrogen treatments, the highest and lowest biological yields were observed in 125% fertilizer requirement (15141 kg.ha-1) and 50% fertilizer requirement (12640 kg.ha-1), respectively. The highest and lowest yields were observed in the treatments of supply of 120% (6498 kg.ha-1) and 60% (4933 kg.ha-1) of water requirement, respectively. The rate of yield increase in 120% water requirement treatment was 9, 18, and 24%, compared to 100, 80, and 60% of water requirement treatments, respectively. However, the highest WUE was obtained in 60% crop water requirement treatment and providing 100% of nitrogen consumption (3.08 kg.m-3). In water deficit conditions, providing 100% of the plant's nitrogen requirement keeps WUE in high level. If the amount of nitrogen is reduced, WUE was also decreased. The highest and lowest ANUE were observed in 100% water requirement treatment fertilized with 75% of nitrogen requirement (79 kg.kg-1) and 120% water requirement treatment fertilized with 100% nitrogen requirement (9 kg.kg-1), respectively. With decreasing water consumption, the rate of stem remobilization increased to the highest level, which was observed in the treatment of 60% of water requirement fertilized with 100% nitrogen requirement. The highest chlorophyll concentration was related to the 100% crop water requirement treatment fertilized with 100% of nitrogen requirementirement.

Keywords

Main Subjects


  1. Afkari, A. 2018. Effects of drought stress and nitrogen fertilizer rate on some physiological characteristics, essential oil percentage, and yield of basil (Ocimum basilicum ). Iranian Journal of Medicinal and Aromatic Plants 33 (6): 1047-105.doi: 10.22092/ijmapr.2018.112686.2085.
  2. Akhavan, 2015. The application of drip irrigation system (Tape) in wheat cultivation. Extension Manual, Number 83: 201.
  3. Al-Ghzawi, A., Khalaf, Y., Al-Ajlouni, Z., AL-Quraan, N., Musallam, I., and Hani, N. J. A. 2018. The effect of supplemental irrigation on canopy temperature depression, chlorophyll content, and water use efficiency in three wheat (Triticum aestivum and T. durum Desf.) varieties grown in dry regions of jordan. Agriculture 8 (5): 1-23.
  4. Baradaran Firoz Abadi, M., Elahian Noughabi, M., Rahimzadeh, F., Moghadam, M., Ranji, Z., and Rarsaeian, M. 2004. Effect of deferent levels of continuous water strees on quantity and quantity of tree sugar beet lins, Journal of Suger beet 19 (2): 133-144.
  5. Bole, J. B., and Dubetz, S. 2006. Effect of irrigiation and nitrogen fertilizer on the yield and protein content of soft white spring wheat. Canadian. Journal of Plant Science 66: 281-289. https://doi.org/10.4141/cjps86-041.
  6. Dordas, C. A., and Sioulas, C. 2008. Safflower yield, chlorophyll content, photosynthesis, and water use efficiency response to nitrogen fertilization under rained conditions. Industrial Crops and Products 27 (1): 75- 85. https://doi.org/10.1016/j.indcrop.2007.07.020.
  7. Ebertseder, T., R. Guster, U. Hege, R. Brandhuber and Schmidhalter, U. 2003. Strategies for site-specific nitrogen fertilization with respect to long-term environmental demands. In: Proceeding of the 4th European Conference on Precision Agriculture. J. V. Stafford (Ed.). Wageningen Academic Publishers. The Netherlands.
  8. El-Gendy, A. G., Gohary, E. l., Omer, E. A., Hendawy, S. F., and Hussein, M. S. 2015. Effect of nitrogen and potassium fertilizer on herbage and oil yield of chervil plant (Anthriscus cerefolium). Industrial Crops and Products 69: 167-174. https://doi.org/10.1016/j.indcrop.2015.02.023.
  9. Garrido-Lestache, E., Lopez-Bellido, R. J., and Lopez-Bellido, L. 2005. Durum wheat quality Under Mediterranean conditions as affected by N rate, timing and splitting, N form and S fertilization. European Journal of Agronomy 23: 265-278. https://doi.org/10.1016/j.eja.2004.12.001.
  10. Ghobadi, R., Shirkhani, A., and Jalilian, A. 2015. Effects of water steres and nitrogen fertilizer on yield, itacomponents, water and nitrogen use efficiency of corn (Zea mays L.) CV. SC. 704. Applied Field Crops Reserch (Pajouhesh and Sazandegi) 28 (106): 79-87.
  11. Gholinezhad, 2014. Effect of water deficit stress, different rates of nitrogen and plant density on remobilization, current photosynthesis and grain yield in sunflower. Journal of Oil Plant Production (1): 44-63.
  12. Guadra, G., Padovan, S., and Delogu, G. 2004. Grain yield, nitrogen use efficiency and baking quality of old and modern Italian bread- wheat cultivar s grown at different nitrogen levels. European Journal of Agronomy 21: 181-192. https://doi.org/10.1016/j.eja.2003.08.001.
  13. Gonzalez, A., Bermjo, V., and Gimeno, B. S. 2010. Effect of different physiological traits on grain yield in barley grown under irrigated and terminal water deficit conditions. Journal of Agricultural Science 148: 319-328. DOI: https://doi.org/10.1017/S0021859610000031.
  14. Hatfield, J. L., and Prueger, J. H. 2004. Nitrogen over-use, under-use, and efficiency. In Proceedings of the 4th International Crop Science Congress (Vol. 26).
  15. Fan, J., Wu, L., Zhang, F., Yan, S., and Xiang, Y. 2017. Evaluation of drip fertigation uniformity affected by injector type, pressure difference and lateral layout. Irrigation and Drainage 66 (4): 520-529. https://doi.org/10.1002/ird.2136.
  16. Fatih, H. 2010. Effect of nitrogen and zinc fertilizers on physiological characteristics of two barley cultivars in autumn, under drought stress conditions. Master Thesis in Agriculture, Faculty of Agriculture, University of Kurdistan.
  17. Fooladvand, H. R., Niazi, J. A., Shirazi Agriculture, H. and Jokar, L. 2006. Interaction of different amounts of irrigation and nitrogen on wheat yield. Journal of Agricultural Sciences, Twelfth Year, 4: 786-779.
  18. Forouzi, M., Ehteshami, M. R., Isfahani, M. and Rabiee, m. 2016. Study of dry matter remobilization rate and current photosynthesis in different seed sizes of four wheat cultivars (Triticum aestivum ). Iranian Journal of Seed Science and Research 3 (1): 61-47.
  19. Jafarinejadi, A. R., Moezi, A. A. A., Mousavi Fazl, S. M. H. and Sayyad, Gh. A. 2011. The efficiency of different types of nitrogen fertilizers and wheat yield. Journal of Agriculture 33 (2): 91-100.
  20. Hong, W. P., Lielei, M., Yongqing, Q. I., Xingran, L., Yugui, J., Yanjun, Sh., and Changming, L. 2017. Impact of varied irrigation on field water budegts crops yields in the North china plain: Rainfed vs. irrigation double cropping system. Agricuture Water Management 190: 42-54. https://doi.org/10.1016/j.agwat.2017.05.007.
  21. Hosseini, R., Gashi, S., Soltani, A., Kalateh, M., and zahed. M. Effect of Nitrogen Fertilizer on Nitrogen Consumption Indices in Wheat (Triticum aestivum L.). Iranian Journal of Crop Research 11 (2): 300-306.
  22. Kirigwi, F. M., M. Van Ginkel, R. Trethowan, R. G. Sears, S. Rajaram, and G. M. Paulsen. 2004. Evaluation of selection strategies for wheat adaptation across water regimes. Euphytica 135: 361-371. https://doi.org/10.1023/B:EUPH.0000013375.66104.04.
  23. Ma, S. C., Wang, T. C., Guan, X. K., and Zhan, X. 2018. Effect of sowing time and seeding rate on yield components and water use efficiency of irrigated wheat by regulating the growth redundancy and physiological traits of root and shoot. Field Crops Research 221: 166-174. https://doi.org/10.1016/j.fcr.2018.02.028.
  24. Majidian, M., Ghalavand, A., Karimian, N., and Kamgar haghighi, A. A. 2008. Effects of nitrogen different amounts, manure and irrigation water on yield and yield components of corn. Eleectronic Journal of Crop Production 1 (2): 67-85.
  25. Mirzakhani, M. 2019. Response of nitrogen use efficiency and agronomic characteristics of irrigated wheat to rate, time and method of nitrogen application. Iranian Journal of Field Crop Science 50 (2): 77-87. Doi: 22059/ijfcs.2018.245329.654402.
  26. Papakosta, D. K., and Gagianas, A. A. 1991. Nitrogen and dry matter accumulation, remobilization, and losses for Mediterranean wheat during grain filling. Crop Science Society of America, Agronomy Journal 83: 864-870. https://doi.org/10.2134/agronj1991.00021962008300050018x.
  27. Paredes, P., Pereira, L. S., Rodrigues, G. C., Botelho, N., and Torres, M. O. 2017. Using the FAO dual crop coefficient approach to model water use and productivity of processing pea (Pisum sativum) as influenced by irrigation strategies. Agricultural Water Management 189: 5-18. https://doi.org/10.1016/j.agwat.2017.04.010.
  28. Pouri, K., Siosemardeh, A., Sohrabi, Y., and Soltani, A. 2019. Crop phenotyping for wheat yield and yield components against drought stress. Cereal Research Communications 47: 383-393. https://doi.org/10.1556/0806.47.2019.05.
  29. Rajala, A., Hakala, K., Kela, P. M., Muurinen, S., and Peltonen-Sainio, P. 2009. Spring wheat response to timing of water deficit through sink and grain filling capacity. Field Crops Research 114: 27-263. https://doi.org/10.1016/j.fcr.2009.08.007.
  30. Recous, S., and J. M. Machet. 2019. Short term immobilization and crop uptake of fertilizer nitrogen applied to irrigated wheat: Effect of date application in spring. Plant and Soil 206: 137-149. https://doi.org/10.1023/A:1004377006602.
  31. Shi, S., Zhou, S., Yin, J., Li, Q., Zhang, Y., Cheng, M., and Zhang, C. 2013. Effects of water and fertilizer coupling on photosynthetic characteristics in flag leaves and yield of irrigated wheat under high yield condition. Journal of Triticeae Crops 33 (3): 549-554.
  32. Si, Z., Zain, M., Mehmood, F., Wang, G., Gao, Y., and Duan, A. 2020. Effects of nitrogen application rate and irrigation regime on growth, yield, and water-nitrogen use efficiency of drip-irrigated irrigated wheat in the North China Plain. Agricultural Water Management 231: https://doi.org/10.1016/j.agwat.2020.106002.
  33. Tahmasebi Sarvestani, Z., Rouhi, A., and Secondary teacher, S., and M. 2011. Quantitative and Qualitative Characteristics of Yield of Dryland Wheat Genotypes under Supplementary Irrigation Conditions, Iranian Journal of Crop 3 (1): 47-55
  34. Timsina, T., Singh, U., Badaruddin, M., Meisner, C., and Amin, M. R. 2001. Cultivar, nitrogen, and water effects on productivity, and nitrogen-use efficiency and balance for rice–wheat sequences of Bangladesh. Field Crop Research 72: 143-161. https://doi.org/10.1016/S0378-4290(01)00171-X.
  35. Yan, S., Wu, Y., Fan, J., Zhang, F., Qiang, S., Zheng, J., and Zou, H. 2019. Effects of water and fertilizer management on grain filling characteristics, grain weight and productivity of drip-fertigated irrigated wheat. Agricultural Water Management 213: 983-995. https://doi.org/10.1016/j.agwat.2018.12.019.
  36. Zheng, J., Fan, J., Zhang, F., Yan, S., and Xiang, Y. 2018. Rainfall partitioning into throughfall, stemflow and interception loss by maize canopy on the semi-arid Loess Plateau of China. Agricultural Water Management 195: 25-36. https://doi.org/10.1016/j.agwat.2017.09.013.
CAPTCHA Image
  • Receive Date: 13 March 2021
  • Revise Date: 24 November 2021
  • Accept Date: 30 November 2021
  • First Publish Date: 30 November 2021