Field-scale soil moisture bridges the spatial-scale gap between drought monitoring and agricultural yields
Field-scale soil moisture bridges the spatial-scale gap between drought monitoring and agricultural yields
Soil moisture is highly variable in space and time, and deficits (i.e., droughts) play an important role in modulating crop yields. Limited hydroclimate and yield data, however, hamper drought impact monitoring and assessment at the farm field scale. This study demonstrates the potential of using field-scale soil moisture simulations to support high-resolution agricultural yield prediction and drought monitoring at the smallholder farm field scale. We present a multiscale modeling approach that combines HydroBlocks a physically based hyper-resolution land surface model (LSM) with machine learning. We used HydroBlocks to simulate root zone soil moisture and soil temperature in Zambia at 3 h 30 m resolution. These simulations, along with remotely sensed vegetation indices, meteorological data, and descriptors of the physical landscape (related to topography, land cover, and soils) were combined with district-level maize data to train a random forest (RF) model to predict maize yields at district and field scales (250 m). Our model predicted yields with an average testing coefficient of determination (R2) of 0.57 and mean absolute error (MAE) of 310 kgha-1 using year-based cross-validation. Our predicted maize losses due to the 2015 2016 El Niño drought agreed well with losses reported by the Food and Agriculture Organization (FAO). Our results reveal that soil moisture is the strongest and most reliable predictor of maize yield, driving its spatial and temporal variability. Soil moisture was also a more effective indicator of drought impacts on crops than precipitation, soil and air temperatures, and remotely sensed normalized difference vegetation index (NDVI)-based drought indices. This study demonstrates how field-scale modeling can help bridge the spatial-scale gap between drought monitoring and agricultural impacts.
1827-1847
Vergopolan, Noemi
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Xiong, Sitian
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Estes, Lyndon
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Wanders, Niko
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Chaney, Nathaniel W.
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Wood, Eric F.
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Konar, Megan
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Caylor, Kelly
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Beck, Hylke E.
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Gatti, Nicolas
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Evans, Tom
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Sheffield, Justin
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9 April 2021
Vergopolan, Noemi
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Xiong, Sitian
c1653f04-26e3-4274-b900-ae228fd36b36
Estes, Lyndon
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Wanders, Niko
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Chaney, Nathaniel W.
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Wood, Eric F.
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Konar, Megan
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Caylor, Kelly
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Beck, Hylke E.
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Gatti, Nicolas
fe3ac7aa-64a1-4a2a-a518-9502f8da8b3a
Evans, Tom
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Sheffield, Justin
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Vergopolan, Noemi, Xiong, Sitian, Estes, Lyndon, Wanders, Niko, Chaney, Nathaniel W., Wood, Eric F., Konar, Megan, Caylor, Kelly, Beck, Hylke E., Gatti, Nicolas, Evans, Tom and Sheffield, Justin
(2021)
Field-scale soil moisture bridges the spatial-scale gap between drought monitoring and agricultural yields.
Hydrology and Earth System Sciences, 25 (4), .
(doi:10.5194/hess-25-1827-2021).
Abstract
Soil moisture is highly variable in space and time, and deficits (i.e., droughts) play an important role in modulating crop yields. Limited hydroclimate and yield data, however, hamper drought impact monitoring and assessment at the farm field scale. This study demonstrates the potential of using field-scale soil moisture simulations to support high-resolution agricultural yield prediction and drought monitoring at the smallholder farm field scale. We present a multiscale modeling approach that combines HydroBlocks a physically based hyper-resolution land surface model (LSM) with machine learning. We used HydroBlocks to simulate root zone soil moisture and soil temperature in Zambia at 3 h 30 m resolution. These simulations, along with remotely sensed vegetation indices, meteorological data, and descriptors of the physical landscape (related to topography, land cover, and soils) were combined with district-level maize data to train a random forest (RF) model to predict maize yields at district and field scales (250 m). Our model predicted yields with an average testing coefficient of determination (R2) of 0.57 and mean absolute error (MAE) of 310 kgha-1 using year-based cross-validation. Our predicted maize losses due to the 2015 2016 El Niño drought agreed well with losses reported by the Food and Agriculture Organization (FAO). Our results reveal that soil moisture is the strongest and most reliable predictor of maize yield, driving its spatial and temporal variability. Soil moisture was also a more effective indicator of drought impacts on crops than precipitation, soil and air temperatures, and remotely sensed normalized difference vegetation index (NDVI)-based drought indices. This study demonstrates how field-scale modeling can help bridge the spatial-scale gap between drought monitoring and agricultural impacts.
More information
Accepted/In Press date: 17 February 2021
Published date: 9 April 2021
Additional Information:
Publisher Copyright:
© 2021 Author(s).
Identifiers
Local EPrints ID: 471431
URI: http://eprints.soton.ac.uk/id/eprint/471431
ISSN: 1027-5606
PURE UUID: 776e5326-9408-4302-9e50-1efebe3d1d28
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Date deposited: 08 Nov 2022 17:58
Last modified: 16 Apr 2024 01:47
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Contributors
Author:
Noemi Vergopolan
Author:
Sitian Xiong
Author:
Lyndon Estes
Author:
Niko Wanders
Author:
Nathaniel W. Chaney
Author:
Eric F. Wood
Author:
Megan Konar
Author:
Kelly Caylor
Author:
Hylke E. Beck
Author:
Nicolas Gatti
Author:
Tom Evans
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