Demand-Driven Technologies for Sustainable Maize ... - IITA

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169Effects of sole cropping, intercropping androtation with legume trap-crops on Strigacontrol and maize grain yield in farmers’fields in the northern Guinea savannaI. Kureh 1 and A.Y. Kamara 21Department of Plant Science, Institute for Agricultural ResearchAhmadu Bello University, Zaria, Nigeria2IITA, Ibadan, NigeriaAbstractOn-farm trials were conducted in 2001 to 2003 in the northernGuinea savanna of Nigeria to evaluate integrated Striga hermonthicacontrol methods under farmer-managed conditions. These includedintercropping a Striga-resistant maize variety with cowpea (Vignaunguiculata L.) and also cropping this maize in rotation with legume trapcrops– soybean [Glycine max (L) Merr.] and cowpea. IntercroppingStriga-tolerant maize variety, Acr. 97 TZL Comp. 1-W, with cowpeaor rotating it with the soybean cultivar TGX1448-2E) or the cowpeacultivar IT93K452-1 proved effective in reducing Striga incidence andinfestation compared with three years of continuously cropped maizeas control. Striga incidence was reduced by 73% in intercropped maize,64% in maize after two years soybean, and by 68% in maize after twoyears of cowpea than in continuously cropped maize. However, maizegrain yield was considerably reduced when intercropped with cowpea,probably due to competition from the cowpea crop. Maize grain yieldwas 28% higher after one year of soybean and 21% higher after oneyear of cowpea than in the continuously cropped maize. Maize grainyield was 85% higher after two years of soybean, and 66% higher aftertwo years of cowpea than in the continuously cropped maize.RésuméDes tests en milieu paysan ont été conduits de 2001 à 2003 dans lenord de la savane guinéenne au Nigeria, pour évaluer les méthodes delutte intégrée de Striga hermonthica dans les conditions de gestion del’agriculteur. Ces conditions incluaient une variété de maïs résistanteà Striga, var. 97TZL Comp.1-W, cultivée en association avec le niébé[Vigne unguiculata L. (cultivar IT93K452-1)] et la rotation de culturede maïs avec le soja qui est une légumineuse - culture piège [Glycinemax (L) Merr. (cultivar TGX1448-2E)] ou le niébé. L’association de
170la variété de maïs tolérant à Striga avec le niébé ou la rotation avecles cultivars de soja ou de niébé a été effi cace dans la réduction del’incidence et l’infestation de Striga, comparé à trois années de culturede maïs en continue, utilisée comme témoins. L’incidence du Strigaest reduit de 73% dans le maïs cultivé en association, 64% dans lemaïs après 2 années de culture de soja et de 68% dans le maïs après2 ans de culture de niébé comparativement à la culture continue demaïs. Cependant, le rendement grain de maïs était considérablementréduit quand il était associé au niébé. Ceci est probablement du à lacompétition due au niébé. Le rendement grain du maïs était 28% plusélevé après une année de soja et 21% plus élevé après une année deniébé comparativement à la culture continue de maïs.Le rendement grain du maïs cultivé était de 85% plus élevé aprèsdeux années de soja et 66% plus élevé après deux années de niébécomparativement à la culture continue de maïs.IntroductionStriga hermonthica (Del.) Benth is an important parasitic weed of cerealsin the semi-arid tropics. In decreasing order of susceptibility, maize (Zeamays L.), sorghum [Sorghum bicolor (L.) Moench] and millet (Eleusinecoracana L.) are the most important hosts. The parasite also infectsupland rice (Oryza sativa L.). It has been estimated that about 40 to70 million ha of cereal crops are severely or moderately infested inWest African countries (Lagoke et al. 1991). Severe Striga infestationcan cause 70-80% yield loss in maize and sorghum and losses can bemuch higher under heavy infestations, sometimes resulting in total cropfailure (Emechebe et al. 2004). Farmers often have to abandon infestedagricultural lands as a result of high soil infestation by noxious weeds(Kroschel 1999). The present trend of moving away from traditionalpractice of soil fertility restoration, which included prolonged fallowand intercropping, towards continuous cereal monocropping to meetthe food needs of an increasing population has intensifi ed the Strigaproblem. In addition to many factors already known, grazing cattle,crop seeds, and wind contribute to the spread of Striga infestation tonew areas (Berner et al. 1996). The problem is compounded by thehigh reproductive capacity of Striga plants. A single Striga plant canproduce over 50,000 seeds, which can remain viable in the soil for15-20 years (Musselman 1987; Doggett 1988).Striga research in Africa has a long history and a range of effectivecomponent control technologies has been identifi ed (Parker andRiches 1993). Control options for S. hermonthica range from useof leguminous trap-crops to the use of resistant host-crop cultivars.Leguminous trap-crops stimulate suicidal germination of Striga seedsand, therefore, reduce the seed bank and improve soil fertility. Schulz
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iDemand-Driven Technologies forSust
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iiiContentsPrefacePréfaceForewordA
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vAssessment of Striga infestation i
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viiPrefaceThe West and Central Afri
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ixendosperm maize varieties, 95 TZE
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Les agriculteurs de la savane guin
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xiiiForewordMaize (Zea mays L) is o
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xvAvant proposLe maïs (Zea mays L)
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xviiFifth Biennial West and Central
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xixNigeria26 Abdullahi, Y.M. NAERLS
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1Section1Breeding, SeedSystems and
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4skills of the scientists and impro
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6collaborating scientists. This is
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8fi ndings to their peers. They are
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10Figure 3. Funds received by indiv
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12Percentage PercentageYearFigure 5
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14Figure 9. Coefficient of variatio
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16Figure 15. Total maize grain prod
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18Table 2. Capacity Building of NAR
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20DiscussionResults of the analyses
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22the Lead Country Concept was not
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24Badu-Apraku, B., M.A.B. Fakorede,
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26et des lignées dotées de résis
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28Overview of the strategy for deve
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30Table 1. Characteristics of extra
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32Table 2. Performance of extra-ear
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34Table 3. cont’dInbredlineParent
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36different germplasm and for placi
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38Figure 1. Clustering of 35 extra-
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40Table 4. Number of inbred lines i
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42M’Boob, S.S., 1986. A regional
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44sur la performance de leurs hybri
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46Table 1. Mean grain yield (Mg ha
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48Table 2. Means for grain yield an
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50Table 4. Estimates of GCA effects
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52employed to exploit non-additive
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54deux traitements de sol (O, T). L
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56Table 1. Characteristic of 15 par
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58Table 4. Diallel analysis of vari
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60Table 6. Number of adapted x adap
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62ConclusionThe results of this stu
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64Combining ability of diverse maiz
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66S. hermonthica and S. asiatica. Y
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68Table 2.Mean squares of grain yie
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70Table 4. Mean squares of grain yi
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72Table 5. Estimates of general com
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74Table 7. Estimates of general com
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76yield under Striga infestation. T
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78Kim, S.K., V.O. Adetimirin and A.
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80Maize accounts for between 30 and
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82VII, XI and V that had grain yiel
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84Table 3. Inter- and intra-cluster
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86interest, including early, medium
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88IntroductionThe multi-environment
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90Table 1: Sums of squares (SS) exp
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922Table 3: Average proportion of t
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94genotypes within the target sets.
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96residual interaction matrix has b
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98Effects of farmers’ seed source
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100known. The objective of this stu
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102AFigure 1. (A) Percentage seeds
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104zFigure 5. Mean days to 50% silk
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106ReferenceAsiedu, E.A., Twumasi-A
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108Mexique et les USA. Dans les ann
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110In collaboration with the Intern
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112to farmers. Recommendations had
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114maize, the highest grain yield a
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116Figure 1. Trend of land area cul
Page 139 and 140: 118ConclusionIn conclusion, the Ins
Page 141 and 142: 120Valencia, J.A. and S.A. Breth. u
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Page 145 and 146: 124chimique. L’effet relatif de l
Page 147 and 148: 126Figure 1: Rainfall pattern in Sa
Page 149 and 150: 128Percentage PercentageFigure 2: M
Page 151 and 152: 130Table 2. Effect of organic mater
Page 153 and 154: 132Yield increase and relative yiel
Page 155 and 156: 134Table 5. Relative grain and stov
Page 157 and 158: 136Dudal, R., 2002. Forty years of
Page 159 and 160: 138Residual benefits of soybean gen
Page 161 and 162: 140The cultivation of leguminous cr
Page 163 and 164: 142(IITA), natural fallow and a lat
Page 165 and 166: 144on exchangeable Ca, exchangeable
Page 167 and 168: 146Table 4. Rotation† and fertili
Page 173 and 174: 152in the top 0-15 cm layer and als
Page 175 and 176: 154inoculation and nitrogen fertili
Page 177 and 178: 156RésuméLes besoins du maïs en
Page 179 and 180: 158Table 1. Monthly distribution an
Page 181 and 182: 160was applied about 5 cm deep, mad
Page 183 and 184: 162Table 3. Effects of legumes and
Page 185 and 186: 164Figure 3: Grain yield of maize a
Page 187 and 188: 166ConclusionFrom the results of th
Page 189: 168Tarawali, G., 1991. The residual
Page 193 and 194: 172It is necessary to validate that
Page 195 and 196: 174Table 2. Effects of previous cro
Page 197 and 198: 176of cowpea, than in the farmers
Page 199 and 200: 178AcknowledgementsThe authors than
Page 201 and 202: 180Potential of drought-tolerant ma
Page 203 and 204: 182potential in comparison to the t
Page 205 and 206: 184ha -1 . Fields were planted on J
Page 207 and 208: 186Table 3. Means for days to silki
Page 209 and 210: 188DiscussionThe observed effects o
Page 211 and 212: 190the yield potential of the genot
Page 213 and 214: 192Edmeades, G.O., J. Bolanos, M. H
Page 215 and 216: 194Genotypic variation of soybean f
Page 217 and 218: 1962002). Therefore, high BNF in so
Page 219 and 220: 198Experimental layout, planting an
Page 221 and 222: 200At 8 WAP, fi ve plants were rand
Page 223 and 224: 202Figure 1. Relationships between
Page 225 and 226: 204signifi cant correlation (P ≤
Page 227 and 228: 206Table 4. Total N accumulation (k
Page 229 and 230: 208Table 5. Total P in grain (kg ha
Page 231 and 232: 210Table 6. Grain yield (kg ha -1 )
Page 233 and 234: 212colonization in previous RP plot
Page 235 and 236: 214(Table 8). However, within speci
Page 237 and 238: 216maize-after-soybean plots over t
Page 239 and 240: 218The observed trends in grain yie
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220in soybean than in maize grain d
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222IITA (International Institute of
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224Snedecor G.W., Cochran G. (1980)
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226irrigated conditions in the Sahe
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228Figure 1: Variation des tempéra
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230L’espérance de la matrice de
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232Tableau 3. Moyennes des caractè
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234Tableau 6. Table d’ANOVA du mo
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236Tableau 8. Table d’ANOVA du mo
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238seconde stratégie répond bien
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240
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242
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244RésuméDes enquêtes sur les ma
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246Field surveysField surveys were
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248Table 1.PathogensMean incidence
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250Table 3. Correlation matrix betw
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252Table 8. Correlation matrix betw
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254Signifi cant correlations were f
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256NCRE, 1994. Annual Report Camero
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258faibles réactions qui indiquent
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260(b) A no-choice situation. In th
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262Table 2. Ovipositional responses
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264Table 5. Larval feeding response
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266Figure 1. Profiles of colonizing
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268on moderately resistant and susc
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270CCE, (Commission des Communauté
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272RésuméLe Striga est une contra
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274the baseline for environmental m
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276Table 1. Percentage of crop and
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278(Emechebe et al. 1991) may have
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280ReferencesAnonymous, 1996. Stati
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282The use of spicy plant oils agai
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284The objectives of the present st
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286% mortality100908070605040302010
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288saturated atmosphere in the dark
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290(Gyllenhal) in stored chick-peas
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292intercropped with groundnut, and
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294du Striga. Les observations ont
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296Tableau 1. Incidence des plants
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298Tableau 4. Contd.LibellésUnité
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300soudure. Le traitement maïs ass
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302Herbicide resistant maize: a nov
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304Figure 1. Striga-prone areas in
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306developed herbicide resistant li
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308geo-referenced data from a farm-
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310Table 2: Grain yield and Striga
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312AcknowledgementsThis research wa
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314Effects of maize-cowpea intercro
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316In Cameroon, maize is commonly i
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318Table 1. Relative abundance and
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320Table 4. Maize stem borers’ st
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322were the predominant predator sp
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324on insect infestation and the as
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326Kareiva, P.M., 1983. Finding and
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328
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330impliquées dans la production d
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332Table 1: Scores assigned for fac
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334Table 2. Characteristics of wome
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336Table 5. Spearman rank correlati
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338farmers are given the appropriat
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340RésuméUne étude combinée de
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342ZamfaraStateKatsinaStateFigure 1
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344Table 1. Relative radii of the f
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346Table 4. Number of crops grown i
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348Figure 3: Concentric circles ref
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350No. Maize farmersFigure 4: Facto
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352Table 8. Trend of farmers rating
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354Gyasi, K.O, L.N. Abateisina, T.
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356Bénin. Seed quality was determi
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358Tableau 1. Moyenne des différen
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36070000Nombre de plants à I’hec
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362ISTA (International Seed Testing
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364Togolese Institute of Agricultur
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366variété améliorée et un tém
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368Tableau 2. Cycle des différente
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370Tableau 6. Rendement des variét
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372Tableau 7. Evolution des rendeme
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374300000250000Maïs Mais purMaïs/
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376- Au niveau des tests associatio
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378à base de maïs dans le Nord de
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380Two States (Kaduna and Katsina),
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382Table 1. Percentage of farm hous
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384Table 3. Socio-economic factors
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386AcknowledgementThe authors are g
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388Unexploited yield and profitabil
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390and input combinations. A number
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392The production function in equat
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394host of socio-economic and insti
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396Table 3. Frequency distribution
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398The adjusted R-squared value and
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400Assefa, A., 1995. Analysis of pr
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402Socio-economics of community-bas
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404seed at affordable price to farm
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406Table 1. Socio-economic profiles
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408Table 3. Average labor costs and
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410ReferencesAhmed, B., 1994. Econo
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412communautaire de semences de ma
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414producing QPM seed at the commun
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416Table 1. Cost elements (N/ha) in
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418Table 3. Gross income (N/ha) fro
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420Conclusion and RecommendationsTh
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422Effets de la rotation et de l’
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424Tableau 1. Caractéristiques phy
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426Tableau 3. Composition chimique
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428Figure 1. Evolution des rendemen
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430Maïs-grain (kg.ha -1 )Maïs-gra
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432Tableau 9. Successions culturale
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434Maïs-grain (kg.ha -1 )350030002
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436
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438
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440ont été analysés pour leur co
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442A=(M’-M) x 100/M + A o(1)where
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444Table 1. Physicochemical composi
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446Table 2. Steeping time and varie
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448germination. In general, the pea
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450after cooking of maize malted fl
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452Marero, L. M., E.M. Payuma, A.R.
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454Effects of wheat flour replaceme
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456considerably and this is attribu
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458resulting products (fl ours, dou
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460Table 1. Physico-chemical proper
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462CMS 8806 CMS 8704CMS 9015 CMS 85
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46439.8We ight(g)39.639.439.2390%10
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466He, H. and R.C. Hoseney, 1991. D
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468Adaptation et utilisation de var
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470Figure 1. Distribution mensuelle
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472chaque semaine. L’essai a dur
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474Resultats et DiscussionsTests ag
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476Tableau 2. Proportions des ingr
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478Tableau 5. Composition de l’al
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480Tableau 7. Coûts financiers de
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482des demandeurs à payer et est d
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484ConclusionNotre étude montre qu
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486
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488
Page 511 and 512:
490Breeding, Seed Production and St
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4921. Propose approaches/innovation
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494identifi cation, planning and im
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496
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