Rice (Oryza sativa L.) establishment methods under irrigated and rain-fed lowlands of Kenya: Effect on growth and yield

Paper Details

Research Paper 01/01/2019
Views (392) Download (19)
current_issue_feature_image
publication_file

Rice (Oryza sativa L.) establishment methods under irrigated and rain-fed lowlands of Kenya: Effect on growth and yield

CW. Muchira, JM. Kinama, JM. Kimani
Int. J. Agron. Agri. Res.14( 1), 26-36, January 2019.
Certificate: IJAAR 2019 [Generate Certificate]

Abstract

An experiment was conducted at Ahero and Mwea during July 2017 to January 2018 season; to assess effect of direct seeding (DS) and transplanting (TP) on growth and yield of four rain-fed ( NERICA1 & 4, Komboka, MWUR4) and four irrigated (SARO5, Komboka, NIBAM11, MWIR2) varieties, on Kenyan lowlands. A split plot on randomized complete block design (RCBD) was used with three replicates; three seeds hill-1 were dibbled, later thinned to one on DS plots, one seedling was transplanted on TP plots. A (20×15) cm spacing used on both DS and TP plots. Data was subjected to analysis of variance, separation of means using Turkey’s test at 5% probability level. Results on plant height, productive tillers hill-1, grain weight hill-1, 1000 seed weight, yields (rain-fed) showed non-significance (p> 0.05). Days to flowering onset (rain-fed) had significant differences on DSR and TPR. Productive tillers hill-1 (Irrigated) were significant (p<0.05) while grain yield, grain weight hill-1, 1000 seed weight, days to flowering onset (irrigated) were not significant (p>0.05). Grain yield (t ha-1) on rain-fed varieties indicated TP-Komboka (5.6), TP-NERICA1 (4.6) compared to Komboka and MWUR 4 (DS) at 4.9 and 4.3 respectively. Grain yield (t ha-1) (irrigated) had no yield gain on either TP or DS though they differed significantly with NIBAM 11 and MWIR 2 (TP) at 4.9 and 6.9 while DS- (MWIR2 and NIBAM11) at 5.9 and 4.8 respectively. Harvest index positively correlated to grain yield (rain-fed; r=0.693, p<0.001) (irrigated r =0.696, p<0.001). Variable costs were TP (KES: 81,850) compared to DS (KES 61,900). Although DS yielded less compared to TP, the aspect of water and labour saving would motivate its wide adoption contributing to enhanced rice productivity.

VIEWS 30

Africa Rice Center. 2011. Boosting Africa’s Rice Sector-Consultative Group on International Agricultural Research (CGIAR). Research for Development Strategy 2011-2020.

Ashfaq M, Haider MS, Khan AS, Allah SU. 2014. Breeding Potential of the Basmati Rice Germplasm under Water Stress Condition. African Journal of Biotechnology 11, 6647-6657.

Ashrafuzzaman M, Islam MR, Ismail MR, Shahidullah SM, Hanafi MM. 2009. Evaluation of six aromatic rice varieties for yield and yield contributing characters. International Journal of Agriculture and Biology 11, 616-620

Bozorgi HR, Faraji A, Danesh RK. 2011. Effect of plant density on yield and yield components of rice. World Applied Sciences Journal 12, 2053-2057.

Chauhan BS, Singh K, Ladha JK, Kumar V, Saharawat YS. 2013. Weedy Rice: An Emerging Threat for Direct-seeded Rice Production Systems in India. Journal of Rice Research 1, 106. Available at DOI: 10.4172/jrr.1000106.

Diagne A, Amovin-Assagba E, Futakuchi K, Wopereis MCS. 2013. Estimation of cultivated area, number of farming households and yield for major rice-growing environments in Africa. Pages 35-45, UK: CABI

Dingkuhn M, Schnier HF, De Datta SK, Dorffling K, Javellana C, Pamplona R. 1990. Nitrogen fertilization of direct-seeded flooded vs. transplanted rice: II. Interactions between canopy properties. Crop Science 30, 1284-1292.

Emongor RA, Mureithi FM, Ndirangu SN, Kitaka DM, Walela BM. 2009. The Rice Value Chain in Kenya With Reference to Rice Producers. Available at http://www.kari.org/biennialconference /conference12/docs.pdf

Fischer G, Tubiello FN, Van-Velthuizen H, Wiberg D. 2007. Climate change impacts on irrigation water requirements; Global and regional effects of mitigation: 1990-2008. Technological Forecasting & Social Change 74, 1083-1107. Available at https://doi.org/10.1016/j.techfore.2006.05.021

Gelalcha Solomon and Hanchinal RR. 2013. Correlation and path analysis in yield components in spring bread wheat (Triticum aestivum) genotypes under irrigated condition in Southern India. African Journal of Agricultural Research 8(24), 3186-3192.

Getachew Mekonnen, Mitiku Woldesenbet, Eskinder Yegezu. 2017. Determination of Critical Period of Weed-Crop Competition in Rice (Oryza sativa L.) in Bench Maji and Kaffa Zone, South Western Ethiopia. Journal of Plant Sciences 5(3), 90-98. Retrieved from doi: 10.11648/j.jps.20170503.11

Hailu Tefera. 2010. Variability and association of characters in rice (Oryza sativa L.) cultivars. MSc. thesis, Alemaya university of Agriculture Dire Dawa, Ethiopia.

International Rice Research Institute. 2008. “Rice Production Training Module: Method of Planting Rice,” IRRI, Los Barios, pp.1-13.

Islam MS, Hasanuzzamanb M, Rokonuzzamanc M, Nahard K. 2009. Effect of split application of nitrogen fertilizer on morpho-physiological parameters of rice genotypes. International Journal of Plant Production 3(1), 52-61. Available at www.ijpp.info, online version 1735-8043

Jaetzold R, Schmidt H, Hornetz B, Shisanya C. 2005. Farm Management Handbook of Kenya. Natural Conditions and Farm Management Information, 2nd edition (Vol. II Part C) GTZ, Eschborn, Germany.

Kabir MH, Bhuiya MSU, Saha A, Khan MAH, Nur-E-Elahi. 2009. “Effect of Crop Establishment Method and Time of Nitrogen Application on the Productivity of Boro Rice in Lowland Ecosystem,” Bangladesh Rice Journal 14(1), 1-6.

Kimani JM, Tongoona P, Derera J, Nyende AB. 2011. Upland Rice Varieties Development through Participatory Plant Breeding. ARPN Journal of Agricultural and Biological Science 6(9), 39-49.

Krishnan PB, Ramakrishnan KR, Reddy VR. 2011. High-temperature effects on rice growth, yield, and grain quality. In Donald L. Sparks. Academic Press Burlington. Advances in Agronomy 111, 87-206. Available at http://www.nal.usda.gov/

Kukal SS, Aggarwal GC. 2002. Percolation losses of water in relation to puddling intensity and depth in a sandy loam rice (Oryza sativa) field. Agricultural Water Management 57, 49-59.

Kumar V, Ladha JK. 2011. Direct seeded rice: Recent development & future research needs. Advances in Agronomy 111, 297-413. Available at https://doi.org/10.1016/B978-0-12-387689-8.00001

Mati BM, Wanjogu R, Odongo B, Home PG. 2011. Introduction of the system of rice intensification in Kenya: experiences from Mwea irrigation scheme. Springer-Verlag. Paddy & Water Environment 9(1), 145-154.

Mohammad T, Deva W, Ahmad Z. 2002. Genetic variability of different plant and yield characters in rice. Sarhad Journal of Agriculture 18, 207-210.

Naresh RK, Gupta Raj K, Singh B, Kumar Ashok, Shahi UP, Pal Gajendra, Singh Adesh, Yadav Ashok Kumar, Tomar SS. 2010. Assessment of No-Tillage and Direct Seeding Technologies in rice-wheat rotation for Saving of Water and Labour in Western IGP. Progressive Agriculture an International Journal 10(2), 205-218. Online Version ISSN: 0976-4615

National Irrigation Board. 2008. Strategic Plan 2008-2013, Ministry of water and irrigation- National Irrigation Board of Kenya p. 48.

Okech JN, Wawire NW, Okor WA, Okiyo TO, Otieno VO, Onyango G. 2010. A comparative economic analysis of the traditional and improved upland rain-fed rice varieties in Kisumu District, Kenya. 12th KARI Scientific Conference Proceedings 410-414.

Okech JNO, Takeya H, Asanuma S, Kouko WO, Kore WAO, Otieno K. 2008. Analysis of Preconditions for the Diffusion of New Rice for Africa (NERICA) in Bungoma District, Kenya. Paper presented at 11th KARI biennial Scientific Conference in November in Nairobi (unpublished).

Onyango AO. 2014. Exploring Options for Improving Rice Production to Reduce Hunger and Poverty in Kenya World Environment 4(4), 172-179. Available at DOI: 10.5923/j.env.20140404.03

Pandey S, Velasco L. 1999. Economics of direct seeding in Asia, patterns of adoption and research priorities. International Rice Research. Newsletter 24, 6-11.

Patra SK, Padhi AK, Mishra SN, Sahoo BK. 1992. Response of rain-fed direct seeded upland rice to levels and time of nitrogen application; Oryza 29, 265-299.

Ratna M, Begum S, Husna A, Dey SR, Hossain MS. 2015. Correlation and Path Coefficients Analyses in Basmati Rice. Bangladesh Journal of Agricultural Research 40, 153-161. Available at http://dx.doi.org

Republic of Kenya, ministry of agriculture. 2004. Strategy for Revitalizing Agriculture 2000-2014. Ministry of Agriculture and Ministry of Livestock and Fisheries Development, Nairobi.

Seyoum M, Sentayehu A, Bantte K. 2011. Evaluation of Upland NERICA Rice (Oryza sativa L.) genotypes for grain yield and yield components along an altitude gradient southwest Ethiopia. Journal of Agronomy 10(4), 105-111. Available at https://scialert.

Singh Y, Singh G, Johnson D, Mortimer M. 2005a. Changing from transplanted rice to direct seeding in the rice-wheat cropping system in India. In: Rice is Life: Scientific Perspectives for the 21st Century, Tsukuba, Japan: Proceeding of the Word Rice Research Conference, 4-7 November 2004; pp. 198-201.

Thakur RB. 1993. Performance of summer rice (Oryza sativa) to varying levels of nitrogen; Indian Journal of Agronomy 38(2), 187-190.

VSN International Limited. 2011. GenStat statistical software 15th Edition.