More accurate specification of water supply shows its importance for global crop production
More accurate specification of water supply shows its importance for global crop production
Warming temperatures tend to damage crop yields, yet the influence of water supply on global yields and its relation to temperature stress remains unclear. Here we use satellite-based measurements to provide empirical estimates of how root zone soil moisture and surface air temperature jointly influence the global productivity of maize, soybeans, millet and sorghum. Relative to empirical models using precipitation as a proxy for water supply, we find that models using soil moisture explain 30–120% more of the interannual yield variation across crops. Models using soil moisture also better separate water-supply stress from correlated heat stress and show that soil moisture and temperature contribute roughly equally to historical variations in yield. Globally, our models project yield damages of −9% to −32% across crops by end-of-century under Shared Socioeconomic Pathway 5-8.5 from changes in temperature and soil moisture. By contrast, projections using temperature and precipitation overestimate damages by 28% to 320% across crops both because they confound stresses from dryness and heat and because changes in soil moisture and temperature diverge from their historical association due to climate change. Our results demonstrate the importance of accurately representing water supply for predicting changes in global agricultural productivity and for designing effective adaptation strategies.
753-763
Proctor, Jonathan
0a074970-798d-47a6-aeaa-4d311db80e0b
Rigden, Angela
5bf5defc-2240-4196-9449-adecea3c8af2
Chan, Duo
4c1278dc-7f39-4b67-b1cd-3f81f55f4906
Huybers, Peter
48e9a517-aa2a-40f1-96ef-06d76b19291c
19 September 2022
Proctor, Jonathan
0a074970-798d-47a6-aeaa-4d311db80e0b
Rigden, Angela
5bf5defc-2240-4196-9449-adecea3c8af2
Chan, Duo
4c1278dc-7f39-4b67-b1cd-3f81f55f4906
Huybers, Peter
48e9a517-aa2a-40f1-96ef-06d76b19291c
Proctor, Jonathan, Rigden, Angela, Chan, Duo and Huybers, Peter
(2022)
More accurate specification of water supply shows its importance for global crop production.
Nature Food, 3 (9), .
(doi:10.1038/s43016-022-00592-x).
Abstract
Warming temperatures tend to damage crop yields, yet the influence of water supply on global yields and its relation to temperature stress remains unclear. Here we use satellite-based measurements to provide empirical estimates of how root zone soil moisture and surface air temperature jointly influence the global productivity of maize, soybeans, millet and sorghum. Relative to empirical models using precipitation as a proxy for water supply, we find that models using soil moisture explain 30–120% more of the interannual yield variation across crops. Models using soil moisture also better separate water-supply stress from correlated heat stress and show that soil moisture and temperature contribute roughly equally to historical variations in yield. Globally, our models project yield damages of −9% to −32% across crops by end-of-century under Shared Socioeconomic Pathway 5-8.5 from changes in temperature and soil moisture. By contrast, projections using temperature and precipitation overestimate damages by 28% to 320% across crops both because they confound stresses from dryness and heat and because changes in soil moisture and temperature diverge from their historical association due to climate change. Our results demonstrate the importance of accurately representing water supply for predicting changes in global agricultural productivity and for designing effective adaptation strategies.
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Published date: 19 September 2022
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Local EPrints ID: 481977
URI: http://eprints.soton.ac.uk/id/eprint/481977
PURE UUID: 01079cf0-8fbe-424f-880f-4105e313e6dc
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Date deposited: 14 Sep 2023 16:45
Last modified: 18 Mar 2024 04:15
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Author:
Jonathan Proctor
Author:
Angela Rigden
Author:
Duo Chan
Author:
Peter Huybers
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