Global sensitivity analysis of crop yield and transpiration from the FAO-AquaCrop model for dryland environments
Global sensitivity analysis of crop yield and transpiration from the FAO-AquaCrop model for dryland environments
The application of crop models towards improved local scale prediction and precision management requires the identification and description of the major factors influencing model performance. Such efforts are particularly important for dryland areas which face rapid population growth and increasing constraints on water supplies. In this study, a global sensitivity analysis on crop yield and transpiration was performed for 49 parameters in the FAO-AquaCrop model (version 6.0) across three dryland farming areas with different climatic conditions. The Morris screening method and the variance-based Extended Fourier Amplitude Sensitivity Test (EFAST) method were used to evaluate the parameter sensitivities of several staple crops (maize, soybean or winter wheat) under dry, normal and wet scenarios. Results suggest that parameter sensitivities vary with the target model output (e.g., yield, transpiration) and the wetness condition. By synthesizing parameter sensitivities under different scenarios, the key parameters affecting model performance under both high and low water stress were identified for the three crops. Overall, factors relevant to root development tended to have large impacts under high water stress, while those controlling maximum canopy cover and senescence were more influential under low water stress. Parameter sensitivities were also shown to be stage-dependent from a day-by-day analysis of canopy cover and biomass simulations. Subsequent comparison with AquaCrop version 5.0 suggests that AquaCrop version 6.0 is less sensitive to uncertainties in soil properties.
AquaCrop, Dryland, Sensitivity analysis, Transpiration, Yield
1-15
Lu, Yang
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Chibarabada, Tendai
0b6cb82d-38e1-4d83-a5e0-62ce1cdf4189
McCabe, Matthew
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De Lannoy, Gabrielle
d0cfef12-3e6d-4580-a440-897830362e5e
Sheffield, Justin
dd66575b-a4dc-4190-ad95-df2d6aaaaa6b
15 July 2021
Lu, Yang
6d9d9d4f-3177-4265-b03b-34d7129ec95c
Chibarabada, Tendai
0b6cb82d-38e1-4d83-a5e0-62ce1cdf4189
McCabe, Matthew
c3d8a141-3f6d-4c01-a60f-4bb03ce543cf
De Lannoy, Gabrielle
d0cfef12-3e6d-4580-a440-897830362e5e
Sheffield, Justin
dd66575b-a4dc-4190-ad95-df2d6aaaaa6b
Lu, Yang, Chibarabada, Tendai, McCabe, Matthew, De Lannoy, Gabrielle and Sheffield, Justin
(2021)
Global sensitivity analysis of crop yield and transpiration from the FAO-AquaCrop model for dryland environments.
Field Crops Research, 269, , [108182].
(doi:10.1016/j.fcr.2021.108182).
Abstract
The application of crop models towards improved local scale prediction and precision management requires the identification and description of the major factors influencing model performance. Such efforts are particularly important for dryland areas which face rapid population growth and increasing constraints on water supplies. In this study, a global sensitivity analysis on crop yield and transpiration was performed for 49 parameters in the FAO-AquaCrop model (version 6.0) across three dryland farming areas with different climatic conditions. The Morris screening method and the variance-based Extended Fourier Amplitude Sensitivity Test (EFAST) method were used to evaluate the parameter sensitivities of several staple crops (maize, soybean or winter wheat) under dry, normal and wet scenarios. Results suggest that parameter sensitivities vary with the target model output (e.g., yield, transpiration) and the wetness condition. By synthesizing parameter sensitivities under different scenarios, the key parameters affecting model performance under both high and low water stress were identified for the three crops. Overall, factors relevant to root development tended to have large impacts under high water stress, while those controlling maximum canopy cover and senescence were more influential under low water stress. Parameter sensitivities were also shown to be stage-dependent from a day-by-day analysis of canopy cover and biomass simulations. Subsequent comparison with AquaCrop version 5.0 suggests that AquaCrop version 6.0 is less sensitive to uncertainties in soil properties.
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Accepted/In Press date: 17 May 2021
e-pub ahead of print date: 25 May 2021
Published date: 15 July 2021
Keywords:
AquaCrop, Dryland, Sensitivity analysis, Transpiration, Yield
Identifiers
Local EPrints ID: 449637
URI: http://eprints.soton.ac.uk/id/eprint/449637
ISSN: 0378-4290
PURE UUID: 51684765-b01a-4511-b5ee-95c435963633
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Date deposited: 10 Jun 2021 16:30
Last modified: 17 Mar 2024 06:36
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Contributors
Author:
Tendai Chibarabada
Author:
Matthew McCabe
Author:
Gabrielle De Lannoy
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