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Tropentag, September 15 - 17, 2021, hybrid conference

"Towards shifting paradigms in agriculture for a healthy and sustainable future"


Intercropping Maize with G. Sepium and Pigeonpea Enhances Productivity and Resilience of Cropping Systems in Semiarid Tanzania

Anthony Kimaro1, Johannes Michael Hafner2, Christine Lamanna3, Peter Steward4, Todd Rosenstock5

1World Agroforestry (ICRAF), Tanzania Country Programme, Tanzania
2Leibniz Centre for Agric. Landscape Res. (ZALF), Sustainable Land Use in Developing Countries (SusLAND), Germany
3World Agroforestry, Systems Theme
4World Agroforestry , Systems Theme, Kenya
5World Agroforestry (ICRAF), Land Health Decisions, DR Congo


Abstract


Low and sporadic precipitations adversely affect cropping system resilience in semiarid tropics. However, crop diversification through intercropping enhance agroecosystem resilience. We tested whether intercropping maize with Gliciridia sepium and/or pigeonpea improves productivity and drought resistance of maize under semiarid conditions. Our study adopted a split-split-plot experiment to test the effects of intercropping (maize monoculture, sole pigeonpea, maize-Gliricidia, maize-pigeonpea and maize-pigeonpea-Gliricidia), fertilisers (with and without) and rainfall (ambient and drought). Drought was induced using the above-canopy rainout shelters which intercepts 50% of the ambient rainfall. No significant effects of rainout shelters was note on air temperature and relative humidity above the maize canopy, but photosynthetically radiation (PAR) was reduced by 15.8%. Gravimetric soil moisture was also reduced by 12.5%. As expected, the drought treatment reduced soil moisture, but without creating artificial growing conditions for crops. Significant effect of intercropping was noted in 2019 and 2020 seasons, which is attributed to the combined impacts of weather variability and interactions of maize with G. sepium and pigeonpea. Significant interactions between treatments (intercropping, fertiliser and drought) was noted in 2019 with G. sepium-pigeonpea intercropping under fertilisation and ambient rainfall significantly suppressing maize yield relative maize monoculture. However, maize- G. sepium and maize-pigeonpea intercropping did not reduce maize grain yield relative, suggest that farmers can diversify their fields with either G. sepium or pigeonpea without compromising yields of maize even in drought prone seasons like 2019. In 2020, fertilisation improved maize grain yields under drought by 63% compared to ambient rainfall. Heavy and well distributed precipitations throughout the 2020 cropping season (961 mm) account for the reduction of maize yields under ambient as the rainfall amount received in the drought treatment (790 mm) was above the long-term average (425 mm) for semiarid areas of Tanzania. Overall maize yield in intercropping in 2020 was similar to the yield obtained with maize monoculture. Also, maize resistance, measured as yield loss due to drought, was higher in intercropping and land equivalent ratios were above 1 in both growing seasons. This study show intercropping maize with G. sepium or pigeonpea sustains productivity and improve resilience of maize cropping systems.


Keywords: Agroforestry, Climate Change, Crop diversification, Drought, Maize yield


Contact Address: Anthony Kimaro, World Agroforestry (ICRAF), Tanzania Country Programme, P.O. Box 6226, Dar-es-Salaam, Tanzania, e-mail: a.kimaro@cgiar.org


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