Abstract
Cropping is responsible for substantial emissions of greenhouse gasses (GHGs) worldwide through the use of fertilizers and through expansion of agricultural land and associated carbon losses. Especially in sub-Saharan Africa (SSA), GHG emissions from these processes might increase steeply in coming decades, due to tripling demand for food until 2050 to match the steep population growth. This study assesses the impact of achieving cereal self-sufficiency by the year 2050 for 10 SSA countries on GHG emissions related to different scenarios of increasing cereal production, ranging from intensifying production to agricultural area expansion. We also assessed different nutrient management variants in the intensification. Our analysis revealed that irrespective of intensification or extensification, GHG emissions of the 10 countries jointly are at least 50% higher in 2050 than in 2015. Intensification will come, depending on the nutrient use efficiency achieved, with large increases in nutrient inputs and associated GHG emissions. However, matching food demand through conversion of forest and grasslands to cereal area likely results in much higher GHG emissions. Moreover, many countries lack enough suitable land for cereal expansion to match food demand. In addition, we analysed the uncertainty in our GHG estimates and found that it is caused primarily by uncertainty in the IPCC Tier 1 coefficient for direct N2 O emissions, and by the agronomic nitrogen use efficiency (N-AE). In conclusion, intensification scenarios are clearly superior to expansion scenarios in terms of climate change mitigation, but only if current N-AE is increased to levels commonly achieved in, for example, the United States, and which have been demonstrated to be feasible in some locations in SSA. As such, intensifying cereal production with good agronomy and nutrient management is essential to moderate inevitable increases in GHG emissions. Sustainably increasing crop production in SSA is therefore a daunting challenge in the coming decades.
Highlights
This study provided insight into the consequences for greenhouse gasses (GHGs) emis‐ sions of achieving future cereal self‐sufficiency in sub‐Saharan Africa (SSA) through sce‐ narios with different levels of intensification and/or area expansion and different nutrient management variants
We showed that for the 10 studied countries jointly GHG emissions from cereal cropping can increase up to 500% in 2050 compared to 2015 for scenarios in which area expan‐ sion is a main pathway to increase production
We show that intensification of cereal production with effi‐ cient use of fertilizers will moderate the increase in GHG emissions, it requires a large increase in nutrient inputs
Summary
We used four scenarios to assess GHG emissions as affected by agricultural intensification or area extension for 10 countries in SSA (i.e. Burkina Faso, Ethiopia, Ghana, Kenya, Mali, Niger, Nigeria, Tanzania, Uganda and Zambia) and five ce‐ reals (i.e. maize, millet, rice, sorghum and wheat). TA B L E 1 Weighted average current (2015) and estimated future (four scenarios) N input (high efficiency variant) on cereal land, total cereal area and land use expansion needed for full self‐ sufficiency in 2050 for five cerealsa and 10 countries in sub‐Saharan Africa (SSA)b. We used the high‐efficiency variant to estimate N input requirements for all cereals and scenarios This implies that for maize, an agronomic nitrogen use efficiency (N‐AE, extra grain yield per kg of fertilizer applied) was assumed of 52 kg/kg for Scenarios 1–3, and 46 kg/kg for Scenario 4 (ten Berge et al, 2019). Sequestration of C from grass due to LUC Sequestration of C from forest due to LUC SOC sequestration due to LUC (c)
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