Effect of Different Tillage Methods and Management of Plant Residues on Agronomy Traits of Wheat and Organic Carbon and Nitrogen of Soil in a Three-years Crop Rotation

Document Type : Scientific - Research

Authors

1 Department of Agrotechnology, Faculty of Agriculture, Ferdowsi University of Mashhad, Mashhad, Iran.

2 Khorasan Razavi Agricultural and Natural Resource Research and Education Center, AREEO, Mashhad, Iran.

Abstract

Introduction Conventional tillage methods increase energy costs and lead to the destruction and reduction of water and soil resources, and for a long time, have an adverse effect on soil properties and cause the formation of hard layers. Repeated tillage and deep plowing cause a quick release of carbon dioxide, causing soil and greenhouse effects and, in the long run, undesirable effects on soil characteristics. Compared with conventional tillage, protective tillage reduces the number of agricultural operations, which has many benefits. So that the loss of moisture and destruction of the soil structure would be reduced. Furthermore, the oxidation of organic residues of plants is reduced. Research has shown that the maintenance of a part of the previous crop residues on the surface of soil and the presence of superfluous roots of arable crops in the soil at a rate of two-thirds, reduce the amount of soil compaction in compared with uncoated and unpolluted land. Therefore, the present study was conducted to investigate the effect of different tillage methods and plant residue management on wheat and organic carbon of soil in Mashhad weather conditions.
Materials and Methods
 This research was carried out as a three-year experiment with wheat –rapeseed - wheat rotation as split plots in a randomized complete block design with three replications. In this design, different tillage methods were considered as the main plot and management of plant residues as a subplot. Tillage methods consist of three levels: conventional tillage (plowing + discing + leveling + farrowing + planting with seeding machine), low tillage (light discing + farrowing + planting with seeding machine), and no tillage (direct sowing with seeding machine). Also, the management of plant residues includes three levels: no residues, 30 percent of plant residues, and 60 percent of the previous crop residues. Characteristics of heading and maturity dates, wheat yield and yield components, and soil organic carbon content were investigated.
Results and Discussion
The results showed that the longest time for the occurrence of heading and maturity was observed in conventional tillage treatment. So that, it was only in this treatment the heading and maturity stages occurred on dates more than 170 and 202 days after sowing, respectively. Treatment of no residues with 168.22 days after the sowing date had the most extended date of heading. No-tillage treatment significantly decreased the number of spikes per square meter and 1000-seeds weight. However, there was no significant difference between the levels of plant residues in no-tillage treatment. No-tillage significantly reduced the grain yield of wheat. Though in no-tillage conditions and 30 percent of plant residues, grain yield was significantly higher than 60 percent, and no residues were in the same tillage conditions. The highest grain and biological yields were observed in conventional tillage treatments and in 30 and 60 percent of plant residues. Conventional tillage significantly reduced the soil's organic carbon content. Low tillage treatment at 30 and 60 percent of plant residues observed the highest organic carbon and nitrogen.
Conclusion
Although wheat's grain and biological yield in conventional tillage treatments were more than low tillage and no-tillage, low tillage improved the organic carbon content of the soil, and this phenomenon can have a positive effect on plant yield in the long run. Therefore, preservation of 30 percent of rapeseed residues with low tillage in wheat - rapeseed - wheat is recommended.
 
 
 

Keywords


Alijani, K., Bahra'i, M.J., and Kazemeini, A.R., 2011. Effect of tillage methods and corn residue on growth, yield and yield components of wheat. Iranian Journal of Crop Research 9(3): 486-493. (In Persian with English Summary)
Alvarez, R., and Steinbach, H.S., 2009. A review of the effects of tillage systems on some soil physical properties, water content, nitrate availability and crops yield in the Argentine Pampas. Soil and Tillage Research 104: 1–15.
Asghari Meydani, J., Karimi, A., and Mousavi, S.B., 2012. Effect of different tillage methods on dryland wheat yield and moisture content and apparent density of soil in fallow-wheat rotation in Maragheh. Journal of Agricultural Science and Technology, Water and Soil Science 16(60): 119-129. (In Persian with English Summary)
Ayeneh Band, A., 2005. Crops Rotation. Publications University of Mashhad, Iran. 407 p. (In Persian)
Barjasteh, A.R., 2017. Evaluation of drought stress on wheat (Triticum aestivum L.) and wild oat (Avena ludoviciana L.) competition. Ph.D. Thesis, Faculty of Agriculture, Ferdowsi University of Mashhad, Iran. (In Persian with English Summary)
Barraco, M., DÍaz-Zorita, M., and Duarte, G., 2007. Corn and soybean residue covers effects on wheat productivity under no-tillage practices. In: Wheat Production in Stressed Environment, Springer Publisher, Netherlands. p. 209-216.
Bowman, R.A., Nielsen, D.C., Vigil, M.F., and Aiken, R.M., 2000. Effects of sunflower on soil quality indicators and subsequent wheat yield. Soil Science 165(6): 516-522.
Busari, M.A., and Salako, F.K., 2013. Effect of tillage, poultry manure and NPK fertilizer on soil chemical properties and maize yield on an Alfisol at Abeokuta, south-western Nigeria. Nigerian Journal of Soil Science 23: 206–218.
Castellini, M., and Ventrella, D., 2012. Impact of conventional and minimum tillage on soil hydraulic conductivity in typical cropping system in Southern Italy. Soil and Tillage Research 124: 47–56.
Chegeni, M., Ansari-Dust, S., and Eskandari, H., 2013. Effect of tillage methods and residuals management on some physical properties of soil to achieve sustainable agriculture. Journal of Agricultural Science and Sustainable Production 24(2): 31-40. (In Persian with English Summary)
Crookston, R.K., Kurle, E., and Copeland, P.J., 1991. Rotational cropping sequence affects yields of corn and soybean. Agronomy Journal 83: 108-113.
Ghaffari, A., 2002. Investigating the effect of sardari wheat rotation with oilseed sunflower, chickpea and fallow in rain fed conditions. Journal of Seed and Plant Seed 18(2): 103-110. (In Persian with English Summary)
Herbeck, J., and Murdock, L., 2009. A comprehensive guide to wheat management in Kentucky. Cooperative Extension Service of  College of Agriculture Food and Environment of  University of Kentucky. University of Kentucky.USA.
Imaz, M.J., Virto, I., Bescansa, P., Enrique, A., Fernandez, O., and Karlen, D.L., 2010. Soil quality indicator response to tillage and residue management on semi-arid Mediterranean cropland. Soil and Tillage Research 107: 17–25.
Kamil, B.A, Isildar, A., and Akgul, M., 2005. Tillage impacts on aggregate stability and crop productivity in a loam soil of a dryland in Turkey. Acta Agriculture Scandinavica, Section B. Plant Soil Science 55(3): 214-220.
Karlen, D.L., Wollenhaupt, N.C., Erbach, D.C., Berry, E.C., Swan, J.B., and Eash, N.S., 1994. Long-term tillage effects on soil quality. Soil and Tillage Research 32: 313-324.
Khaje Pour, M.R., 2009. Principles of Agriculture. Publication of Jihad Daneshgahi of Isfahan University, Iran. 398 p. (In Persian)
Khurshid, K., Iqbal, M., Arif, M.S., and Nawaz. A., 2006. Effect of tillage and mulch on soil physical properties and growth of maize. International Journal Of Agriculture And Biology. 593-596.
Koocheki, A.R., Nassiri Mahallati, M., Zare Feyzabadi, A., and Jahanbeen, J., 2004. Evaluation of diversity of Agricultural Systems in Iran. Journal of Research and Development in Agriculture and Horticulture 63: 70-83. (In Persian with English Summary)
Meyer-Aurich, A.M., Gandorfer, G., and Kainz, M., 2009. Tillage and fertilizer effects on yield, profitability, and risk in a corn-wheat-potato-wheat rotation. Agronomy Journal 101: 1538-1547.
Miller, P., McConkey, B., Clayton, G., Brandt, S., Baltensperger, D., and Neil, K., 2002. Pulse crop adaptation in the Northen Great Plains. Agronomy Journal 94: 261-272.
Nassiri Mahallati, M., Koochaki, A., Rezvani, P., and Beheshti, A., 2011. Agro Ecology. Ferdowsi University Publication, Mashhad, Iran. 459 p. (In Persian)
Rao, S.C., and Dao, T.H., 1996. Nitrogen placement and tillage effects on dry matter and nitrogen accumulation and redistribution in winter wheat. Agronomy Journal 188: 10281-1032.
Roozbeh, M., and Pooskani, M.A., 2003. The effect of different tillage methods on wheat yield when in rotation with corn. Iranian Journal Agricultural Science 34(1): 29-38. (In Persian with English Summary)
Rieger, S., Richner, W., Streit, B., Frossard, E., and Liedgens, M., 2008. Growth, yield, and yield components of winter wheat and the effects of tillage intensity, preceding crops, and N fertilization.Europian Journal Of Agronomy. 28: 405-411.
Sadegh Nezhad, H.R., 2013. Sustainable tillage. Technical publication No. 45, Agricultural and Technical Engineering Research Institute. Tehran, Iran. (In Persian)
Sadegh Nezhad, H.R., and Eslami, K., 2006. Comparison of wheat yield by changing soil tillage method. Journal of Agricultural Sciences 12(1): 103-111. (In Persian with English Summary)
Safari, M., 2002. Effect of different tillage methods on yield and yield components of sunflower varieties. Agronomy Journal (Pajohesh and Sazandege) 56: 30-33. (In Persian with English Summary)
Safari, A., Asoudar, M.A., Ghasemi Nejad, M., and Abdali Mashhadi, A., 2013. Effect of conservation of residues, different methods of conservation tillage and planting on physical properties of soil and wheat yield. Journal of Agricultural Knowledge and Sustainable Production 23(2): 49-59. (In Persian with English Summary)
Sainju, U.M., Singh, B.P., Whitehead, W.F., and Wang, S., 2006. Carbon supply and storage in tilled and non-tilled soils as influenced by cover crops and nitrogen fertilization. Journal of Environmental Quality 35: 1507-1517.
Sepideh Dam, S., and Ramurodi, M., 2015. Effect of tillage systems and nitrogen fertilizer on yield, yield components and grain protein of wheat. Journal of Applied Research of Plant Ecophysiology 2(2): 33-36. (In Persian with English Summary)
Shabahang, J., 2015. Evaluation of the effects of management of rotation, tillage operations and plant debris on the physical, chemical and soil carbon sequestration potential. Ph.D. Thesis, Faculty of Agriculture, Ferdowsi University of Mashhad, Mashhad, Iran. (In Persian with English Summary)
Slafer, G.A. 2007. Physiology of determination of major wheat yield components. In: “Wheat Production in Stressed Environments”(Ed: H. Buck). Springer. The Netherlands, pp. 557-565.
Wozniak, A., Wesolowski, M., and Soroka, M., 2015. Effect of long-term reduced tillage on grain yield, grain quality and weed infestation of spring wheat. Journal of Agriculture Science and Technology 17: 899-908.
Wuest, S.B., Albrecht, S.L., and Skirvin, K.W., 2000. Crop residue position and interference with wheat seedling development. Soil and Tillage Research 55: 175-182.
Younesi al-Mawati, M.Y., Solh Jou, A.A., Sharifi, A., Javadi, A., Ashrafizadeh, S.R., and Taki, A., 2015. Guidance for Conservation Tillage and its Application. Agricultural Education Publication. Tehran, Iran. 10-16. (In Persian)
CAPTCHA Image
  • Receive Date: 24 August 2019
  • Revise Date: 15 June 2020
  • Accept Date: 13 July 2020
  • First Publish Date: 27 November 2020