Tillage Effect on Soil Water Content and Corn Yield in a Strip Intercropping System

Ghaffarzadeh, Mohammad; Préchac, F. García; Cruse, Richard M.

doi:10.2134/agronj1997.00021962008900060008x

Cited by 31 publications

(19 citation statements)

References 14 publications

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“…Plants of row 1 generated a second ear in 60% of the time of plants of row 1 and plants of row 12 generated a second ear 40% of the time (Table 3). Similar results were reported by Lesoing and Francis [20] and Ghaffarzadeh et al [26].…”

Section: Grain Yield Componentssupporting

confidence: 91%

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Corn and Soybeans in a Strip Intercropping System: Crop Growth Rates, Radiation Interception, and Grain Yield Components

Verdelli

Acciaresi

Leguizamón

2012

International Journal of Agronomy

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Crop growth rates (CGR), radiation interception (IPAR), yields, and their components were determined in two crops monocultures (using one corn and two soybean genotypes) and in intercropped "strips," during three growing seasons. Corn yield in the strips significantly increased in the three seasons (13-16%) as compared to that in the monocultures. This response was due to increased yield in corn plants of the border rows of the strips, which was highly correlated to an increased IPAR, allowing high CGR at critical crop stages. As a result, more dry matter was partitioned to grain and also an increased number of ears per plant were generated. Conversely, yields of soybeans in the strips were 2 to 11% lower than that in the monocultures, with variable significance depending on soybean cultivar and/or year. Grain number per unit area was the yield component most closely associated to yield variation in both crops. We believe that if yield components of this system are more closely identified, more appropriate genotypes will fit into strip intercropping, thus contributing to the spread of this technique and thus to the sustainability of actual massive monocultured agricultural systems.

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Section: Grain Yield Componentssupporting

confidence: 91%

“…Previous experiments report contrasting responses on the water stress on this yield component [20,21,26,28,29]. It is important to note that two weeks following crop blooming, the young grain does not accumulate dry weight.…”

Section: Treatmentmentioning

confidence: 95%

Corn and Soybeans in a Strip Intercropping System: Crop Growth Rates, Radiation Interception, and Grain Yield Components

Verdelli

Acciaresi

Leguizamón

2012

International Journal of Agronomy

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“…Although significant at only two of six site years, higher plant populations in our border rows were associated with higher yields. Ghaffarzadeh et al (1997) found more ears per plant, more kernels per ear, and higher seed weight from corn in border rows next to soybean than in the inside rows of the corn strips. West and Griffith (1992) found higher yields for intercropped corn at higher populations than in solid‐seeded rows.…”

Section: Resultsmentioning

confidence: 85%

Strip Intercropping Effects on Yield and Yield Components of Corn, Grain Sorghum, and Soybean

Lesoing

Francis

1999

Agronomy Journal

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20 to 24% higher corn yields and 10 to 15% lower soybean yields in adjacent border rows. Strip intercropping of corn (Zea mays L.) and soybean [Glycine Water stress, light quality, and shading are among the max (L.) Merr.] and grain sorghum [Sorghum bicolor (L.) Moench] and soybean may be a viable alternative to monoculture cropping to factors that affect crop yields and yield components at help reduce soil erosion. Careful study of yields and yield components different growth stages. Sixty-three percent shading of can add to understanding crop performance and contribute to design soybean plants caused abscission of half the pods (Mann of more productive systems. Rainfed and irrigated experiments were and Jaworski, 1970). Schou et al. (1978) showed that conducted in eastern Nebraska from 1988 to 1990, on a Sharpsburgshading soybean plants during reproductive growth insilty clay loam (fine, smectitic, mesic Typic Argiudoll), to quantify fluenced seed yield, but seed weight was not changed. strip-intercropping effects on crop yields and yield components. CornEgli and Yu (1991) found that shading from growth border-row and grain sorghum border-row yields next to soybean stages R1 to R5 in soybean reduced seed yields and increased significantly compared with inside rows in the strips. Inseed number, but did not affect seed size. These results creased seed number and seed weight contributed to higher corn are relevant to border soybean rows in strip interborder-row yields, while only seed number increased in grain sorghum border rows. Soybean border-row yields were lower next to all corn cropping. strips and next to grain sorghum strips at the rainfed site. SoybeanEffects of water stress on yield and yield components seed number was lower in border rows next to corn. Corn border-row in corn have been studied extensively. Eck (1986) found increases in seed number and seed weight indicate that competition for that water deficits during vegetative growth reduced resources was important in both reproductive and grain-filling periods; corn kernel number, but had little effect on weight per sorghum border-row increases in seed number suggest competition kernel. Kernel numbers were not affected by water defionly in the reproductive period. Higher corn density in border rows cits during grain filling unless severe deficits were immay further exploit a competitive advantage with soybean in the posed early in the period. Harder et al. (1982) also found reproductive period, perhaps increasing system productivity. Wholekernel number to be influenced by early stress, with system productivity of strip-intercropping systems was a maximum of 4% higher than monocultures of component crops, and gross returns G.W. Lesoing, Univ. of Missouri, 108 W. North Main, Richmond, cropped systems. Carter (1984) and Pavlish (1989) found MO 64085; C.A. Francis, Dep. of Agronomy and Ctr. for Sustainable a high positive correlation between yield and seed num-Agricultural Systems, 225 Keim Hall, Univ. of Nebraska, Lincoln, NE 68583-0949. Univ. of Nebra...

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“…Yang et al (2010) found out that grain yield and N uptake of maize in intercrop were significantly greater than those of sole maize and grain yield of soybean as an intercrop which is significantly lower than sole soybean and their N uptake relatively, thus indicating that intercropping favoured nutrient uptake and growth of maize and the growth of soybean significantly. According to Ghaffarzadeh et al (1997), the basic ideas are based on how different species interact during intercropping competition for resources which arise from varying time of planting, root growth patterns and different resource demands. At high levels of N, under intercropping, Ezumah et al (1987) and Ofori and Stern (1987) observed that grain and legume yield was reduced by the maize intercrop.…”

Section: Contributions Of Intercropping To the Soil Growth And Yieldmentioning

confidence: 99%

In support of a well-planned intercropping systems in south eastern soils of Nigeria: A review

Nweke¹

2018

Afr. J. Agric. Res.

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Soil is the medium for all crop production activities and many of the tropical soils especially soils of South Eastern Nigeria show nutrient deficiency problems after only a short period of cultivation because of the fragile nature and prevailing environmental condition. Land available for further crop production purposes in this area is very limited. To offset some of these problems and boast crop production and yields as well as economic returns, farmers use chemical fertilizers extensively on their field. These chemical fertilizers have their attendant problems ranging from non-availability, high cost, and nutrient imbalances to soil acidity. Consumers of agricultural products and farmers are getting more aware of the dangers caused by these chemicals in soil, environment, and health problems in consuming heavily chemically fertilized crops. An alternative to these chemicals is intercropping due to its environmentally friendly approach. Beside the labour management and adequate use of resources available, intercropping system promotes soil fertility maintenance, conservation and balanced nutrient which will improve crop quality and yield. It ensures farmers' flexibility, reduction against crop failures, weed control and profit maximization. This paper reviews the various contributions of intercropping system to soil fertility enhancement, nutrient recycle, and transfers among intercrop species; its effect on growth and yield of crop species as well as enlightenment on the various terms used to describe the intercropping system.

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Tillage Effect on Soil Water Content and Corn Yield in a Strip Intercropping System

Cited by 31 publications

References 14 publications

Corn and Soybeans in a Strip Intercropping System: Crop Growth Rates, Radiation Interception, and Grain Yield Components

Corn and Soybeans in a Strip Intercropping System: Crop Growth Rates, Radiation Interception, and Grain Yield Components

Strip Intercropping Effects on Yield and Yield Components of Corn, Grain Sorghum, and Soybean

In support of a well-planned intercropping systems in south eastern soils of Nigeria: A review

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