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Maize yield and profitability tradeoffs with social, human and environmental performance: Is sustainable intensification feasible?

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  • Snapp, Sieglinde S.
  • Grabowski, Philip
  • Chikowo, Regis
  • Smith, Alex
  • Anders, Erin
  • Sirrine, Dorothy
  • Chimonyo, Vimbayi
  • Bekunda, Mateete

Abstract

Sustainable intensification (SI) has been regarded as the basis for environmentally sound and equitable agricultural development. Field based assessment of technologies needs to move beyond production and economic performance to include environment, social and human condition. In this study we systematically consider all five domains of SI based on participatory action research (PAR) initiated in 2012 at three Central Malawi sites that varied in agroecology from low to high potential. Fifteen SI indicators were assessed for four technologies: sole maize (Zea mays L.) with 0 and recommended fertilization (69kg Nha−1 and 9kgPha−1), pigeonpea (Cajanus Cajun (L.) Millsp.)-maize intercrop (half rate fertilizer), and doubled up legume rotation (DLR, a pigeonpea-groundnut intercrop) sequenced with maize at half rate fertilizer in that phase. Through radar charts SI performance and tradeoffs were visualized, and causal loop analysis allowed identification of research gaps. SI indicator assessments included crop performance from on-farm trials, profitability, modeled probability of food sufficiency, risk of crop failure and ratings of technologies by women farmers who were engaged in evaluation of technologies through participatory research. The PAR included six mother trials, 236 baby trial farmers and a survey that was carried out with 324 farmers (baby trial farmers plus control farmers) to document socio-economic factors and management practices on focal fields. Replicated mother trials further provided the basis for simulation modeling (APSIM) of weather-associated crop failure risk and slow processes such as soil carbon (C) accrual. Radar charts were used to visualize SI performance of the technologies. Environmental performance of the two pigeonpea-diversified technologies was variable, but generally high compared with sole maize systems, due to gains in vegetative biomass, duration of cover and biological nitrogen (N) fixation. Maize production and economic assessment varied by site, and with steeper tradeoffs for legume diversification in the mesic site, less so in the marginal site. The domains of social and human capacity building were superior for legume integration, notably in terms of diverse diet, food security and farmer preferences (notably, female farmers generally favored legume crops). Performance varied by site with legume systems most beneficial at the most marginal site, including less risk of crop failure than unfertilized maize. Causal loop analyses identified regulators of SI that require further attention, notably: crop-livestock conflicts and opportunities, male-female control of legume crop production, and residue management. Overall, the SI indicators framework provided a systematic means to consider tradeoffs and opportunities associated with novel crop combinations and management practices.

Suggested Citation

  • Snapp, Sieglinde S. & Grabowski, Philip & Chikowo, Regis & Smith, Alex & Anders, Erin & Sirrine, Dorothy & Chimonyo, Vimbayi & Bekunda, Mateete, 2018. "Maize yield and profitability tradeoffs with social, human and environmental performance: Is sustainable intensification feasible?," Agricultural Systems, Elsevier, vol. 162(C), pages 77-88.
    • Handle: RePEc:eee:agisys:v:162:y:2018:i:c:p:77-88
    DOI: 10.1016/j.agsy.2018.01.012
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    5. Abednego Kiwia & David Kimani & Rebbie Harawa & Bashir Jama & Gudeta W. Sileshi, 2019. "Sustainable Intensification with Cereal-Legume Intercropping in Eastern and Southern Africa," Sustainability, MDPI, vol. 11(10), pages 1-18, May.
    6. Anders, Erin J. & Zulu, Leo C. & Jambo, Emmanuel R., 2020. "Limits to grain-legume technology integration by smallholder farmers: The case of time-sensitive labor demands and food security primacy in Malawi," Agricultural Systems, Elsevier, vol. 184(C).
    7. Tafadzwanashe Mabhaudhi & Tendai Polite Chibarabada & Vimbayi Grace Petrova Chimonyo & Vongai Gillian Murugani & Laura Maureen Pereira & Nafiisa Sobratee & Laurencia Govender & Rob Slotow & Albert The, 2018. "Mainstreaming Underutilized Indigenous and Traditional Crops into Food Systems: A South African Perspective," Sustainability, MDPI, vol. 11(1), pages 1-22, December.
    8. Stasiv, Oleh & Kachmar, Oksana & Vavrynovych, Oksana & Arabska, Ekaterina, 2021. "Ecological and economic efficiency of growing maize for grain in short-rotation cultivation of the Western region," Agricultural and Resource Economics: International Scientific E-Journal, Agricultural and Resource Economics: International Scientific E-Journal, vol. 7(2), June.
    9. Nurudeen Abdul Rahman & Asamoah Larbi & Bekele Kotu & Fred Kizito & Irmgard Hoeschle-Zeledon, 2020. "Evaluating Sustainable Intensification of Groundnut Production in Northern Ghana Using the Sustainable Intensification Assessment Framework Approach," Sustainability, MDPI, vol. 12(15), pages 1-17, July.
    10. Saira Batool & Areeba Amer, 2021. "Agriculture Sector in Pakistan (A Historic Analysis)," International Journal of Agriculture & Sustainable Development, 50sea, vol. 3(3), pages 51-56, August.
    11. Maria G. Lampridi & Claus G. Sørensen & Dionysis Bochtis, 2019. "Agricultural Sustainability: A Review of Concepts and Methods," Sustainability, MDPI, vol. 11(18), pages 1-27, September.
    12. Han Wang & Sieglinde S Snapp & Monica Fisher & Frederi Viens, 2019. "A Bayesian analysis of longitudinal farm surveys in Central Malawi reveals yield determinants and site-specific management strategies," PLOS ONE, Public Library of Science, vol. 14(8), pages 1-17, August.
    13. Hammond, James & van Wijk, Mark & Teufel, Nils & Mekonnen, Kindu & Thorne, Peter, 2021. "Assessing smallholder sustainable intensification in the Ethiopian highlands," Agricultural Systems, Elsevier, vol. 194(C).

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