Projected changes in crop yield mean and variability over West Africa in a world 1.5 K warmer than the pre-industrial era
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Published:2018-02-20
Issue:1
Volume:9
Page:119-134
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ISSN:2190-4987
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Container-title:Earth System Dynamics
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language:en
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Short-container-title:Earth Syst. Dynam.
Author:
Parkes BenORCID, Defrance Dimitri, Sultan Benjamin, Ciais Philippe, Wang Xuhui
Abstract
Abstract. The ability of a region to feed itself in the upcoming decades is an
important issue. The West African population is expected to increase
significantly in the next 30 years. The responses of crops to short-term
climate change is critical to the population and the decision makers tasked
with food security. This leads to three questions: how will crop yields
change in the near future? What influence will climate change have on crop
failures? Which adaptation methods should be employed to ameliorate
undesirable changes? An ensemble of near-term climate projections are used to simulate maize,
millet and sorghum in West Africa in the recent historic period (1986–2005) and a
near-term future when global temperatures are 1.5 K above pre-industrial levels to
assess the change in yield, yield variability and crop failure rate. Four
crop models were used to simulate maize, millet and sorghum in West Africa in
the historic and future climates. Across the majority of West Africa the maize, millet and sorghum yields are
shown to fall. In the regions where yields increase, the variability also
increases. This increase in variability increases the likelihood of crop
failures, which are defined as yield negative anomalies beyond 1 standard
deviation during the historic period. The increasing variability increases
the frequency of crop failures across West Africa. The return time of crop
failures falls from 8.8, 9.7 and 10.1 years to 5.2, 6.3 and 5.8 years for
maize, millet and sorghum respectively. The adoption of heat-resistant cultivars and the use of captured rainwater
have been investigated using one crop model as an idealized sensitivity test.
The generalized doption of a cultivar resistant to high-temperature stress
during flowering is shown to be more beneficial than using rainwater
harvesting.
Funder
Seventh Framework Programme European Research Council
Publisher
Copernicus GmbH
Subject
General Earth and Planetary Sciences
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