https://hdl.handle.net/13049/656 2026-04-17T05:15:49Z https://hdl.handle.net/13049/658 Improved crop-management techniques for better groundnut (Arachis liypogaea L.) production in Western Kenya Okiror, M.A.; Okalelio, J.R.; Ipomai, S.O Poor agronomic and husbandry practices are largely responsible for the low yields of groundnuts in Western Kenya. This study was undertaken to develop agronomic practices for increasing groundnut yields by small-hold farmers of Busia, Teso and Siaya districts of Western Kenya. Four experiments-to test sowing time and weed control, to develop a suitable seedbed for groundnut production, to screen available germplasm for high yielding lines, and to test various fertilizer types for use in groundnut production, were set up. These experiments were laid in farmers’ fields. It was observed that an early and finely prepared seedbed increased pod yields significantly (p «; 0.05) above the traditional practice. Such a fine seedbed slowed weed emergence and buildup thereby increasing the weed-free duration for the crop. There were no significant benefits of two weeding operations over the traditional single weeding largely as a result of the seedbed used. Consequently, by investing on a good seedbed, a farmer could save on weeding expenses. Sowing groundnut in the first week of the rains led to a significantly (p s 0.05) higher yield over subsequent dates. Groundnuts responded to fertilizer types differently. (Diammonium phosphate (DAP) and NPK mixed fertilizer applications increased dry pod yields by 22-50% ha'1 over the control. The organic fertilizers, compost and Rhizobiuin inoculant, were not effective in this study. At the rate of 10 t /ha, compost increased pod yield by only 2% over the control. Inoculant application to groundnuts did not lead to significant increases in pod yields. Since no root examination was made for nodules it is not ascertained if the operational factors were extraneous to the isolate or not. Among the entries tested, ICGVSM 90904 and 93535 from 1CRISAT. Malawi consistently Out­ performed the traditional variety, Red Valencia, across locations and over seasons. It is proposed that the seed of the two lines be multiplied and distributed to a nucleus of farmers for further evaluation and multiplication. Due to difficulties in acquiring larger volumes of compost in the farms and the high cost of inorganic fertilizers, a study on combined application of organic and inorganic fertilizers to come up with affordable but effective rates is also proposed. 2006-01-01T00:00:00Z https://hdl.handle.net/13049/657 Assessment of groundnut (Arachis hypogaea L.) genotypes for drought tolerance in Botswana Sesay, A.; Khonga, E. B.; Balole, T. V.; Mashungwa, G. Groundnut (Arachis hypogaea L.) production in Botswana is adversely affected by erratic and unpredictable rainfall resulting in various periods of drought. As part of a programme aimed at developing drought-tolerant cultivars, two field trials were conducted in the 2004-05 cropping season to evaluate 10 groundnut cultivars and 7 breeding lines from the University of Georgia, USA, together with two local varieties, for drought tolerance, using yield under stress and drought-susceptibility indices as selection indices. The trials were conducted under rain-fed and supplementary irrigation conditions at the Botswana College of Agriculture Farm, Notwane. There was a significant reduction in pod yield (P < 0.01), crop growth rate (P < 0.01) and partitioning coefficient (P < 0.01) due to drought stress. Pod yield across cultivars was reduced by an average of 2.3 t ha1 (79.3 %) and 3.5 t ha'1 (88.0 %), from the irrigated to the rain-fed treatment, for the cultivars and the breeding lines, respectively. Drought susceptibility indices for pod yield (Sy), crop growth rate (Sc) and partitioning to reproductive sinks (Sp), used together, identified three cultivars (GAG, 522 and 232) and two breeding lines (C24-124 and C209-6-49) as specifically tolerant to moisture stress. The control cultivars, Nakwana and Peolwane, had the lowest specific leaf area (SLA), 135.9 and 125.8 enrg’1, respectively, indicating high water-use efficiency (WUE) capacity. This variation in drought-tolerance traits could be exploited in a groundnut improvement programme. 2006-01-01T00:00:00Z