Climate-change-induced temporal variation in precipitation increases nitrogen losses from intensive cropping systems: Analysis with a toy model
A simple ‘toy’ model of productivity and nitrogen and phosphorus cycling was used to evaluate how the increasing temporal variation in precipitation that is predicted (and observed) to occur as a consequence of greenhouse-gas-induced climate change will affect crop yields and losses of reactive N that can cause environmental damage and affect human health. The model predicted that as temporal variability in precipitation increased it progressively reduced yields and increased losses of reactive N by disrupting the synchrony between N supply and plant N uptake. Also, increases in the temporal variation of precipitation increased the frequency of floods and droughts. Predictions of this model indicate that climate-change-driven increases in temporal variation in precipitation in rainfed agricultural ecosystems will make it difficult to sustain cropping systems that are both high-yielding and have small environmental and human-health footprints.
Main Authors: | , , , , , , , |
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Format: | Article biblioteca |
Language: | English |
Published: |
Higher Education Press
2022
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Subjects: | AGRICULTURAL SCIENCES AND BIOTECHNOLOGY, Fertilizer Timing, Nitrogen Loss, Precipitation Variability, Toy Model, CROP YIELD, FERTILIZERS, NITROGEN, CROPPING SYSTEMS, Sustainable Agrifood Systems, |
Online Access: | https://hdl.handle.net/10883/22318 |
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Summary: | A simple ‘toy’ model of productivity and nitrogen and phosphorus cycling was used to evaluate how the increasing temporal variation in precipitation that is predicted (and observed) to occur as a consequence of greenhouse-gas-induced climate change will affect crop yields and losses of reactive N that can cause environmental damage and affect human health. The model predicted that as temporal variability in precipitation increased it progressively reduced yields and increased losses of reactive N by disrupting the synchrony between N supply and plant N uptake. Also, increases in the temporal variation of precipitation increased the frequency of floods and droughts. Predictions of this model indicate that climate-change-driven increases in temporal variation in precipitation in rainfed agricultural ecosystems will make it difficult to sustain cropping systems that are both high-yielding and have small environmental and human-health footprints. |
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