Reducing solar radiation forcing uncertainty and Its impact on surface energy and water fluxes
Reducing solar radiation forcing uncertainty and Its impact on surface energy and water fluxes
Downward shortwave radiation R sd determines the surface energy balance, alters evapotranspiration and hydrological conditions, and feeds back to the regional and global climate. Large-scale R sd estimates are usually retrieved from satellite-based top-of-atmosphere radiation and cloud parameters. These estimates are subject to biases and temporal inhomogeneity due to errors in atmospheric parameters, algorithms, and sensor changes. We found that three satellite products overestimate R sd by 8%-10% over Asia for 1984-2006, particularly in high latitudes. We used the model tree ensemble (MTE) machine-learning algorithm and commonly used ensemble averaging methods to integrate ground observations and satellite products. Validations based on test stations and independent networks showed that the MTE approach reduces the median relative biases from 8%-10% to 2%, which is more effective than the ensemble averaging methods. We further evaluated the impacts of uncertainty in radiation forcing on surface energy and water balances using the land surface model Noah-MP. The uncertainty of radiation data affects the prediction of sensible heat the most, and also largely affects latent heat prediction in humid regions. Holding the other variables constant, a 10% positive bias in R sd can lead to a 20%-60% positive bias in the monthly median sensible heat. The simulated hydrological responses to changing radiation forcing are nonlinear as a result of the interactions among evapotranspiration, snowpack, and soil moisture. Our analysis concludes that reducing uncertainty of radiation data is beneficial for predicting regional energy and water balances, which requires more high-quality ground observations and improved satellite retrieval algorithms.
Heat budgets/fluxes, Hydrology, In situ atmospheric observations, Interpolation schemes, Land surface model, Machine learning, Satellite observations
813-829
Peng, Liqing
5a4984ff-9082-4a4c-8e17-991d9eda35cc
Wei, Zhongwang
8c8a2714-1913-4deb-a440-827a382cc775
Zeng, Zhenzhong
7334dbb4-22fd-4b98-ae28-4530716a5901
Lin, Peirong
76a36dac-5584-4cb2-8cb8-fcb056c3b605
Wood, Eric F.
8352c1b4-4fd3-42fe-bd23-46619024f1cf
Sheffield, Justin
dd66575b-a4dc-4190-ad95-df2d6aaaaa6b
1 April 2021
Peng, Liqing
5a4984ff-9082-4a4c-8e17-991d9eda35cc
Wei, Zhongwang
8c8a2714-1913-4deb-a440-827a382cc775
Zeng, Zhenzhong
7334dbb4-22fd-4b98-ae28-4530716a5901
Lin, Peirong
76a36dac-5584-4cb2-8cb8-fcb056c3b605
Wood, Eric F.
8352c1b4-4fd3-42fe-bd23-46619024f1cf
Sheffield, Justin
dd66575b-a4dc-4190-ad95-df2d6aaaaa6b
Peng, Liqing, Wei, Zhongwang, Zeng, Zhenzhong, Lin, Peirong, Wood, Eric F. and Sheffield, Justin
(2021)
Reducing solar radiation forcing uncertainty and Its impact on surface energy and water fluxes.
Journal of Hydrometeorology, 22 (4), .
(doi:10.1175/JHM-D-20-0052.1).
Abstract
Downward shortwave radiation R sd determines the surface energy balance, alters evapotranspiration and hydrological conditions, and feeds back to the regional and global climate. Large-scale R sd estimates are usually retrieved from satellite-based top-of-atmosphere radiation and cloud parameters. These estimates are subject to biases and temporal inhomogeneity due to errors in atmospheric parameters, algorithms, and sensor changes. We found that three satellite products overestimate R sd by 8%-10% over Asia for 1984-2006, particularly in high latitudes. We used the model tree ensemble (MTE) machine-learning algorithm and commonly used ensemble averaging methods to integrate ground observations and satellite products. Validations based on test stations and independent networks showed that the MTE approach reduces the median relative biases from 8%-10% to 2%, which is more effective than the ensemble averaging methods. We further evaluated the impacts of uncertainty in radiation forcing on surface energy and water balances using the land surface model Noah-MP. The uncertainty of radiation data affects the prediction of sensible heat the most, and also largely affects latent heat prediction in humid regions. Holding the other variables constant, a 10% positive bias in R sd can lead to a 20%-60% positive bias in the monthly median sensible heat. The simulated hydrological responses to changing radiation forcing are nonlinear as a result of the interactions among evapotranspiration, snowpack, and soil moisture. Our analysis concludes that reducing uncertainty of radiation data is beneficial for predicting regional energy and water balances, which requires more high-quality ground observations and improved satellite retrieval algorithms.
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e-pub ahead of print date: 23 March 2021
Published date: 1 April 2021
Keywords:
Heat budgets/fluxes, Hydrology, In situ atmospheric observations, Interpolation schemes, Land surface model, Machine learning, Satellite observations
Identifiers
Local EPrints ID: 448790
URI: http://eprints.soton.ac.uk/id/eprint/448790
ISSN: 1525-755X
PURE UUID: eb1476ba-43a0-435d-9625-267af2ba8943
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Date deposited: 05 May 2021 16:56
Last modified: 17 Mar 2024 03:40
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Contributors
Author:
Liqing Peng
Author:
Zhongwang Wei
Author:
Zhenzhong Zeng
Author:
Peirong Lin
Author:
Eric F. Wood
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