Evaluation of the Effect of Rotation and Application Rate of Nitrogen on Yield, Yield Components and Nitrogen Efficiency Indexes in wheat

Document Type : Research Article

Authors

1 Islamic Azad University

2 Ilam University

Abstract

Introduction
There are about 160 species in Brassica genus, which are mostly annuals and biennials. The plants in this genus have potential for fodder uses. The progress in plant breeding science has produced new crop varieties for oil and forage usages. Perko varieties are derived from crosses between tetraploid plants of winter rapeseed (Brassica napus L.Var. napus) and Chinese cabbage (Brassica campestris L. var. sensulato). The new plants are superior to their parents from various aspects. Buko varieties are new amphiploid plants obtained by crossing between tetraploid winter rapeseed, Chinese cabbage and turnips (Brassica campestris L. var. Rapa). Oilseed radish with scientific name (Raphanus sativus L.) is a genus of the Brassica and consumption, oil, green manure, feed and fodder (24). This plant in many countries, including Canada, is cultivated in gardens as cover crop. Oilseed radish grows fast in the cool seasons. Ramtil (Guizotia abyssinica) belongs to the Compositae family, Phasilia (Phaceli atanacetifolia L.) belongs to Boraginaceae family and clover is from Fabaceae family that is grown for feeding purposes.
Materials and Methods
A field experiment was conducted from 2011 to 2012 in the Karezan region of Ilam, Iran (42º33′N, 33º46′E) on a silty-clay with low organic carbon (1.26%) and slightly alkaline soil (pH=7.9). This site is characterized as temperate climate with 370 mm annual precipitation. The experiment was arranged in a split plot based on randomized complete block design with four replications. The main plots consisted of 6 pre-sowing plant treatments (control, Perko PVH, Buko, Clover and Oilseed radish and combination of three plants Ramtil, Phaselia andclover), and sub plots covered four N fertilizer rates including no fertilizer N (Control), 50% lower than recommended N rate, recommended N rate and 50% more than recommended N rate. Winter wheat (cv. Pishtaz) was sown on mid-November with the row spacing of 15 cm and a seeding rate of 200 kg ha-1. Soil samples were collected after harvest of each crop from 0 to 30 cm and 31 to 60 cm soil depths using a soil auger. Wheat grain yield (according to 14% moisture) obtained by harvesting the central area of 3 in 10 m in each plot. Yield components were determined from two randomly selected areas (2m2) within each plot. Plant samples collected at harvest were separated into grain and straw and oven-dried at 60˚C for 72hr. Biomass and grain sub samples analyzed for total N content using a micro-Kjeldahl digestion with sulfuric acid. The terminology of N efficiency parameters was considered according to Delogu et al, (11) and Lopez-Bellido & Lopez-Bellido, (22), Rahimizadeh et al. (30), Limon-Ortega et al. (20) methods.
Results and Discussion
The results showed that there were highly significant differences (P ≤ 0.01) in forage yield. There were also significant differences (P ≤ 0.05) in total dry weight, protein content and protein yield between treatments. Perko varieties produced higher fresh and dry matter yield with 69,586 (kg ha-1) and 7147 (kg ha-1), respectively compared to other varieties. Buko varieties showed greater protein percentage with 23.36 compared to the rest of the varieties. The highest and lowest grain yield, with 8345, and 4491 (kg ha-1) were obtained for Buko; wheat rotation and fallow, wheat rotation, respectively. The highest and lowest nitrogen uptake was obtained for Buko; wheat and clover, wheat rotation, respectively. The differences between the rotations were significant for various agronomic nitrogen efficiency. The rotation of oilseed radish and wheat showed greater nitrogen economic performance with 36.20 kg ha-1. By increasing nitrogen rate agronomic performance decreased with the exception in fallow- wheat. Physiological efficiency of nitrogen in fallow-wheat rotation was more than 39 (kg kg-1) of nitrogen. The maximum efficiency of nitrogen recovery was obtained for oilseed radish: wheat and Perko PVH; wheat rotations with 45% and 36%, respectively. The highest nitrogen harvest index was observed in Buko; wheat rotation: (86.5%), and Perko: wheat (85%) and the lowest nitrogen harvest index was in fallow; wheat (79.28%).
Conclusions
The results showed that Perko; wheat and Buko; wheat rotations due to the higher economic performance in the region were appropriate rotations and were recommended for the study area.

Keywords


1. Abbasi, M. K., Kazmi, M., and Hussan, F. 2005. Nitrogen use efficiency and herbage production of an established grass sward in relation to moisture and nitrogen fertilization. Journal of Plant Nutrition 28: 1693-1708.
2. Brandt, S. A., and Zentner, R. P. 1995. Crop production under alternate rotations on a dark brown chernozemic soil at Scott, Saskatchewan. Canadian Journal of Plant Science 75: 789-794.
3. Brussaard, H. L., De Ruiter, P. C., and Brown, G. G. 2007. Soil biodiversity for agricultural sustainability. Agriculture, Ecosystems and Environment 121: 233-244.
4. Christen, O., Sieling, K., and Hanus, H. 1992. The effect of different preceding crops on the development, growth of winter wheat. European Journal of Agronomy 1: 21-28.
5. Cui, Z., Zhang, F., Chen, X., Miao, Y., Li, J., Shi, L., Xu, J., Ye, Y., Liu, C., Yang, Z., Zhang, Q., Huang, S., and Bao, D. 2008. On-farm evaluation of an in-season nitrogen management strategy based on soil Nmin test. Field Crops Research 105 48-55.
6. Delogu, G., Cattivelli, L., Pecchioni, N., Defalcis, D., Maggiore, T., and Stanca, A. M. 1998. Uptake and agronomic efficiency of nitrogen in winter barley and winter wheat. European Journal of Agronomy 9: 11-20.
7. Dobermann, A. 2006. Nitrogen use efficiency in cereal systems. Available at http// www. regional. org .au/asa/2006/plenary/soil/dobermann.
8. Fan, X., Lin, F., and Kumar, D. 2004. Fertilization with a new type of coated urea. Evaluation for nitrogen efficiency and yield in winter wheat. Journal of Plant Nutrition 25: 853-865.
9. Fauci, M., and Dick, R. 1994. Soil microbial dynamics, short and long-term effects of inorganic and organic nitrogen. Soil Science Society of America Journal 58: 801-806.
10. Hamdi, H., Kashani, A., Bahrain, M. J., Mamghani, R., and Syadat, A. 1992. Determine the growth of perko forage plants (genus Brassica) and the Effect of nitrogen fertilizer on yield due to harvest time in Ahvaz weather conditions. Master's thesis, Shahid Chamran University of Ahvaz. (in Persian).
11. Hiremath, A. J., and Ewel, J. J. 2001. Ecosystem nutrient use efficiency, productivity and nutrient accrual in model tropical communities. Ecosystems 4: 669-682.
12. Hirel, B., Le Gouis, J., Ney, B., and Gallais, A. 2007. The challenge of improving nitrogen use efficiency in crop plants: toward a more central role for genetic variability and quantitative genetics within integrated approaches. Journal of Experimental Botany 58 (9): 2369-2387.
13. Hussain, T., Jilani, G., Parr, J. F., and Ahamd, R. 2001. Transition from conventional to alterative agriculture in Pakistan: The role of green manure in Substitution for inorganic “N” fertilizer’s in a rice – wheat farming systems. American Journal of Alternative Agriculture 10 (3): 133-137.
14. Kashani, A., Bahrain, J., Alami- Saeeid, K., and Mesgarbashi, M. 1986. Science report introduces three varieties of forage plants of the genus Brassica and report preliminary results in Khuzestan. Journal of Agricultural Science 11: 74-78. (in Persian with English abstract).
15. Koocheki, A., Bromand-Rezazadeh, Z., Nasriri- Mahalati, M., and Khoramdel, S. 2012. Evaluation of uptake and nitrogen use efficiency in winter wheat and maize intercropping delay, Journal of Field Crops Research 10 (2): 327-334. (in Persian with English abstract).
16. Lotfolahi, M. 2012. Evaluation of grain protein concentration of wheat by nitrogen foliar application. Journal of Agronomyand Plant Breeding 8 (4): 1-6. (in Persian with English abstract).
17. Garya, P., and Sims, J. R. 1994. Legume cover crops in fallow as an integrated crop livestock alternative in the northern and central Great Plains. Research and Extension Center, University of Wyoming. USA.
18. Guillard, K., Griffin, G., and Pietrzyk, S. 1995. Nitrogen utilization of selected cropping systems in U.S. Northeast. Agronomy Journal 87: 193-199.
19. Limon-Ortega, A., Sayre, K. D., and Francis, C. A. 2000. Wheat nitrogen use efficiency in a bed planting system in northwest Mexico. Agronomy Journal 92: 303-308.
20. Lopez-Bellido, R. J., and Lopez-Bellido, L. 2001. Efficiency of nitrogen in wheat under Mediterranean condition: effect of tillage, crop rotation and N fertilization. Field Crops Research 71: 31-64.
21. Lopez-Bellido, L., Lopez-Bellido, R. J., and Redondo, R. 2005. Nitrogen efficiency in wheat under rainfed Mediterranean conditions as affected by split nitrogen application. Field Crops Research 92: 86-97.
22. Lopez-Bellido, L., Lopez-Bellido, R. J., and Lopez-Bellido, F. J. 2006. Fertilizer Nitrogen Efficiency in Durum Wheat under Rain fed Mediterranean Conditions: Effect of Split Application, Agronomy Journal – Abstract 98: 55-62.
23. Lupashku, M. F. 1980. Perko RVH - a new fodder crop. Vestnik Sel'skokhozyaistvennoi Nauki. Moscow, USSR 4 (6): 94-98.
24. Marianne, S. 1994. Rodale Institute; Managing Cover Crops Profitably, Sustainable Agriculture Research and Education Program, USDA
25. Martens, D. A., and Frankenberger, W. T. 1992. Modification of infiltration rates in an organic-amended irrigated soil. Agronomy Journal 84: 707-717.
26. Miller, P., McConkey, B., Clayton, G., Brandt, S., Baltensperger, D., and Neil, K. 2002. Pulse crop adaptation in the Northern Great Plains. Agronomy Journal 94: 261-272.
27. Moll, R. H., Kamprath, E. J., and Jackson, W. A. 1982. Analysis and interpretation of factors which contribute to efficiency of nitrogen utilization. Agronomy Journal 74: 562-564.
28. Montemuro, F., Maiorana, M., Ferri, D., and Convertini, G. 2006. Nitrogen indicators, uptake and utilization efficiency in a maize and barley rotation cropped at different levels and source of N fertilization. Field Crop Research 99: 114-124.
29. Rahimizadeh, M., Kashani, A., and Zare Faizabadi, A. 2011. Investigation of Pre-Sowing Plants and return of crop residue and the Different Levels of Nitrogen on the Yield Wheat (Triticum aestivum L.). Journal of Field Crops Research 9 (2): 211-221. (in Persian with English abstract).
30. Rahimizadeh, M., Kashani, A., Zare-Feizabadi, A., Koocheki, A. R., and Nassiri-Mahallati, M . 2012. Nitrogen use efficiency of wheat as affected by preceding crop, application rate of nitrogen and crop residues. Australian Journal of Crop Science 4 (5): 363-368.
31. Raun, W. R., and Johnson, G. V. 1991. Improving nitrogen use efficiency for cereal production. Agronomy Journal 91: 357-363.
32. Sieling, K., Schroder, H., Finck, M., and Hanus, M. 1998. Yield, N uptake, and apparent N use efficiency of winter wheat and winter barley grown in different cropping systems. Journal Agriculture Science 131: 375-387.
33. Soon, Y. K., Clayton, G. W., and Rice, W. A. 2001. Tillage and previous effects on dynamics of nitrogen in a wheat-soil system. Agronomy Journal 93: 842-849.
34. Sowers, K. E., Miller, B. C. and Pan, W. L. 1994. Optimizing grain yield in soft white winter wheat with split nitrogen applications. Agronomy Journal 86: 1020-1025.
35. Stacey, G., Burris, R. H., and Evans, H. J. 1992. Biological Nitrogen Fixation. Chapman and Hall, New York.
36. Stevenson, F. C., and Kessel, C. V. 1996. The nitrogen and non-nitrogen rotation benefits of pea to succeeding crops. Canadian Journal of Plant Science 76: 735-745.
37. Subedi, K. D., Ma, B. L., and Xue, A. G. 2007. Planting Date and Nitrogen Effects on Grain Yield and Protein Content of Winter Wheat. Crop Science 47: 36-44.
38. 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.
39. Thuy, N. H., Shan, Y., Singh, B., Wang, K., Cai, Z., Singh, Y., and Buresh, R. J. 2008. Nitrogen supply in rice-based cropping systems as affected by crop residue management. Soil Science Society of America Journal 72: 514-523.
40. Velasco, J. L., Rozas, H. S., Echeverria, H. E. and Barbieri, P. A. 2012. Optimizing fertilizer nitrogen use efficiency by intensively managed spring wheat in humid regions: Effect of split application. Canadian Journal of Plant Science 92: 847-856.
41. Whingwiri, E. E., and Kemp, D. R. 1980. Spikelet development and grain yield of the wheat ear in response to applied nitrogen. Australian Journal of Agricultural Research 31: 637-647.
42. Wiese, A. F., Harman, W. L., Bean, B. W., and Salisbury, C. D. 1994. Effectiveness and economics of dryland conservation tillage systems in the Southern Great Plains. Agronomy Journal 86: 725-730.
43. Zebart, B. J., and Sheard, R.W. 1992. Influence of rate timing of nitrogen fertilization on yield and quality of red winter wheat in Ontario. Plant Science 72: 13-19.
44. Zhao, R. F., Chen, X. P., Zhang, F. S., Zhang, H., Schroder, J., and Romheld, V. 2006. Fertilization and nitrogen balance in a wheat-maize rotation system in North China. Agronomy Journal 98: 935-945.
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