Volume 6, Issue 2, June 2020, Page: 70-75
Comparative Study of Rice Yield Production for Conventional Paddy Rice and Systems of Rice Intensification
Gideon Too, Department of Agricultural and Biosystems Engineering, Faculty of Engineering, University of Eldoret, Nairobi, Kenya
Julius Kipkemboi Kollongei, Department of Agricultural and Biosystems Engineering, Faculty of Engineering, University of Eldoret, Nairobi, Kenya
Japheth Ogalo Onyando, Faculty of Engineering and Technology, Egerton University, Nairobi, Kenya
Emmanuel Chessum Kipkorir, Department of Civil and Structural Engineering, Moi University, Nairobi, Kenya
Received: Apr. 20, 2020;       Accepted: May 8, 2020;       Published: May 29, 2020
DOI: 10.11648/j.ajwse.20200602.13      View  334      Downloads  144
Abstract
Food security in Kenya is at stake due to decline in farm productivity with a combination of an ever increasing population and worsened by global warming. Improvement of agricultural productivity may not be realized soon as rice farmers currently uses traditional method of flooding rice which has been reported to yield low rice. There is need for a deliberate use of new agricultural technologies that improves productivity of rice farming. System of Rice intensification (SRI) provides an opportunity of yield improvements in rice production. This study was undertaken in Ahero Irrigation Scheme to compare yield production of conventional and SRI rice production for IR 2793-80-1 cultivar. The experiment was laid out in a randomized complete block design with three replications. SRI experiments recorded higher number of effective tillers with experiment having a spacing of 20cm by 20cm and transplanted at 8-11 days gave 321 per m2 as compared to 226 effective tillers/m2. Seed yield/plant was highly significant in SRI (39.61 g) as compared to a traditional paddy system (17.32 g). Transplanting rice seedling at the age of 8 to 11 days and at 20cm by 20cm spacing recorded highest seed yield/ha of 4.7 t/ha as compared to traditional flooding which recorded 2.7 t/ha. These results imply that planting young rice seedlings improves grain yield because of increase in number of tillers per square meters, plant height and better plant rooting ability.
Keywords
Systems of Rice Intensification (SRI), Conventional Paddy Rice, Yield, Rice Production
To cite this article
Gideon Too, Julius Kipkemboi Kollongei, Japheth Ogalo Onyando, Emmanuel Chessum Kipkorir, Comparative Study of Rice Yield Production for Conventional Paddy Rice and Systems of Rice Intensification, American Journal of Water Science and Engineering. Vol. 6, No. 2, 2020, pp. 70-75. doi: 10.11648/j.ajwse.20200602.13
Copyright
Copyright © 2020 Authors retain the copyright of this article.
This article is an open access article distributed under the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0/) which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
Reference
[1]
FAO of the United Nations, (2009). Crop prospects and food situation. February (No. 1). Rome: FAO.
[2]
Nyang’au, W. O., Mati, B. M., Kalamwa, K., Wanjogu, R. K., and Kiplagat, L. K., (2014). Estimating Rice Yield under Changing Weather Conditions in Kenya Using CERES Rice Model. International Journal of Agronomy.
[3]
Craciun, I., Craciun, M. (1999). Water and nitrogen use efficiency under limited water supply for maize to increase land productivity. In: Kirda, C., Moutonnet, P., Hera, C., Nielsen, D. R. (Eds.), Crop Yield Response to Deficit Irrigation. Kluwer Academic Publishers, The Netherlands, 87–94.
[4]
Reddy, C. R., Reddy, S. R., (1993). Scheduling irrigation for peanuts with variable amounts of available water. Agricultural Water Management 23, 1–9.
[5]
Mati, M. and Nyamai, M. (2009). System of rice intensification. An information brochure used for Training on SRI in Mwea, Kenya.
[6]
Sujono, J., Matsuo, N., Kazuak, M., and Mochizuki, T. (2011). Improving the water productivity of paddy rice (Oryza sativa L.) cultivation through water saving irrigation treatments. Agricultural Sciences, 2 (2011) 511-517.
[7]
Nwite J. C., B. A. Essien, C. Keke I., Igwe C. A. and Wakatsuki T. (2016). Effect of Different Land Preparation Methods for Sawah System Development on Soil Productivity improvement and Rice Grain Yield in Inland Valleys of Southeastern Nigeria. Advances in Research 6 (2): 1-17.
[8]
Welch, R., Vincent, R., Auffhammer, M., Moya, F., Dobermann, A. and Dawe, D. (2010). Rice yields in tropical/subtropical Asia exhibit large but opposing sensitivities to minimum and maximum temperatures. Sustainability Science, PNAS Early Edition, Pp 6.
[9]
Yoshida, S. (1981). Fundamentals of Rice Crop Science. International Rice Research Institute, Manila, Philippines.
[10]
World Bank Institute, (2008). System of Rice Intensification (SRI): Achieving more with less - A new way of rice cultivation. Overview of SRI - Improving Rice Productivity and Achieving Water Savings. WBI Multimedia Team. Washington, D. C. The Institute.
[11]
Surajit, K. (1981). Principles and Practices of Rice Production. Technology and Engineering. Wiley, New York.
[12]
Nyirenda, M. E., Tarimo, A. K. P. R. and Kihupi, N. I. (2010). Yield response of different local and hybrid rice varieties to different ponding depths of water. Comprehensive Assessment of Water Management in Agriculture. Second RUFORUM Biennial Meeting 20–24 September 2010, Entebbe, Uganda.
[13]
Gomez A. K, Gomez AA (1984). Statistical Procedures of Agricultural Research, New York P: 704.
[14]
Singh C. B, Aujla T. S., Sandhu B. S., Khera K. L. (1996). Effect of transplanting date and irrigation regime on growth, yield and water use in rice (Oryza sativa) in northern India. Indian Journal Agricultural Science 66: 137-141.
[15]
Ravi C. S., Nobuhiko F. and Pabitra B. (2019). System of Rice Intensification Verses Conventional Rice System: Off-farm Field Studies. NASS Journal of Agricultural Sciences; 1 (1): 1-11.
[16]
Gani, A., Kadir, T. S., Jatiharti, A., Wardhana, I. P. and Lal, I. (2002). “The System of Rice Intensification in Indonesia,” in N. Uphoff et al. (eds.), Assessments of the System of Rice Intensification, 58-63.
[17]
Satyanarayana, A., Thiyagarajan, T. M. and Uphoff, N. (2007). Opportunities for water saving with higher yield from the system of rice intensification. Irrigation Science 25: 99–15.
[18]
Uphoff, N. (2001). Scientific issues raised by the System of Rice Intensification: a less water rice cultivation system, In: Hengsdijk H, Bindraban P, editors. Water savings rice production systems. Proceedings of an international workshop on Water saving rice production, Nanjing University China, 2 – 4 April 2001. PRI report No. 33p 69-82.
[19]
Mulu D. (2004). Effect of seedling age, spacing and season on phyllochrons, yield and components of yield with SRI. M. Sc. Thesis. (In:) Report on SRI- visit to Philippines, March 19-28, 2004 (Ed.) Uphoff, N. pp. 5–8.
[20]
Udayakumar, (2005). Studies on System of Rice Intensification (SRI) for seed yield and seed quality. M. Sc. (Agri) Thesis, Acharya N. G. Ranga Agricultural University, Hyderabad.
[21]
San-oh, Y., Sugiyama, T., Yoshita, D., Ookawa, T., Hirasawa, T. (2006). The effect of planting pattern on the rate of photosynthesis and related processes during ripening in rice plants. Field Crops Res., 96: 113–124.
[22]
Krishna, A. and N. K. Biradarpatil, (2009). Influence of seedling age and spacing on seed yield and quality of short duration rice under system of rice intensification cultivation. Karnataka J. Agric. Sci., 22 (1), 53-55.
[23]
Singh, P., Khan, I. M., Singh, S., Tiwari, R. K., Shukla, U. N. and Philip, P. (2014). Performance of physiological basis of rice hybrids under system of rice cultivation. Bangladesh J. Bot., 43 (3): 359-361.
[24]
Reddy, K. R. N., Reddy, C. S., Abbas, H. K., Abel, C. A. and Muralidharan, K. (2008). Mycotoxigenic Fungi, Mycotoxins, and Management of Rice Grains, Toxin Reviews, 27: 3, 287—317.
[25]
Sarath P. Nissanka and Thilak B. (2004). Comparison of Productivity of System of Rice Intensification and Conventional Rice Farming Systems in the Dry-Zone Region of Sri Lanka. 4th International Crop Science Congress.
[26]
Arman E. A. R, Aswaldi A., and Reni M., (2018). The Effects of Planting Range and Weed Management on Growth and Yield of Rice (Oryza sativa L.) Using Modified SRI (The System of Rice Intensification). International Journal on Advance Science Engineering Information Technology, Vol 8 No. 1.
[27]
Avasthe, R. K., Verma, S., Kumar, A and Rahman, H. (2012). Performance of rice (Oryza sativa) varieties at different spacing under system of rice intensification (SRI) in mid hill acid soils of Sikkim Himalayas. Indian Journal of Agronomy 57 (1): 32–37.
[28]
Singh, R. K., Singh, A. N., Ram, H., Rajendra Prasad, S and Chauhan, R. K. 2013. Response of basmati (Oryza sativa L.) rice varieties to System of Rice Intensification (SRI) and conventional methods of rice cultivation. Ann. Agric. Res., 34 (1): 50-56.
[29]
Krupakar Reddy, G. 2004. Varietal performance and spatial requirement of rice under System of Rice Intensification during Kharif season. M. Sc. (Agri) Thesis, Acharya N. G. Ranga Agricultural University, Hyderabad.
[30]
Saravana P. M., Sivakumar G., Srinivaspermal A. P., S Kalaisudarson and Parimala G., (2019). Effect of system of rice intensification on yield attributes towards enhancement of grain yield in rice. Journal of Pharmacognosy and Phytochemistry 2019; 8 (2): 1541-1543.
[31]
Kavitha M. P., Ganesaraja V., Paulpandi V. K., Subramanian R. B. (2010). Effect of Age of Seedlings, Weed Management Practices and Humic Acid Application on System of Rice Intensification. Indian Journal of Agricultural Research 44 (4): 294-299.
[32]
Sawant S., Ritesh K., Kartikeya C., Anoop K. and Sandeep K. (2019). Performance of aromatic varieties and age of seedlings on yield and nutrient uptake of rice under irrigated ecosystem. International Journal of Chemical Studies; 7 (3): 166-169.
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