Advantages of a variable‐resolution global climate model in reproducing the seasonal evolution of East Asian summer monsoon

The East Asian summer monsoon (EASM) is unique among monsoon systems that it features meridional evolution of the summer monsoon. In this study, we evaluate the performances of a Variable‐Resolution Community Earth System Model (VR‐CESM) regionally refined over eastern China (14 km) in reproducing t...

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Veröffentlicht in:International journal of climatology 2023-01, Vol.43 (1), p.575-592
Hauptverfasser: Zhu, Haonan, Zhang, Jie, Xu, Zexuan, Di Vittorio, Alan V., Xin, Xiaoge, Xiao, Chan, Li, Yonghua
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container_issue 1
container_start_page 575
container_title International journal of climatology
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creator Zhu, Haonan
Zhang, Jie
Xu, Zexuan
Di Vittorio, Alan V.
Xin, Xiaoge
Xiao, Chan
Li, Yonghua
description The East Asian summer monsoon (EASM) is unique among monsoon systems that it features meridional evolution of the summer monsoon. In this study, we evaluate the performances of a Variable‐Resolution Community Earth System Model (VR‐CESM) regionally refined over eastern China (14 km) in reproducing the seasonal evolution of EASM precipitation over China. Compared with reference datasets, VR‐CESM shows better performance than the corresponding globally uniform coarse‐resolution model CESM (quasi‐uniform 1°), especially over western China where complex local topography exists. The northward monsoon migration is closely related to low‐level southerly flows and vertical moisture advection, which are more reasonably simulated in VR‐CESM. The four critical timings of the EASM (monsoon onset, withdrawal, peak, and duration) are also better captured in VR‐CESM than in CESM. The corresponding spatial Pearson correlation coefficients of the four critical timings with respect to reference datasets are about 0.1 higher in VR‐CESM than those in CESM. Both models are most accurate in simulating monsoon onset and least accurate at simulating the monsoon peak. The overestimated zonal thermal contrast in CESM is responsible for the earlier monsoon onset and excessive precipitation in September over the Yangtze River valley. Finer resolution in VR‐CESM, especially over the Tibetan Plateau (TP), appears to be a main factor in simulating better zonal thermal contrast and seasonal evolution of the EASM. The four critical timings of EASM (monsoon onset, withdrawal, peak, and duration) are better captured in VR‐CESM. The corresponding spatial correlation coefficients of the four timings with respect to reference datasets are about 0.1 higher in VR‐CESM than those in CESM.
doi_str_mv 10.1002/joc.7796
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Both models are most accurate in simulating monsoon onset and least accurate at simulating the monsoon peak. The overestimated zonal thermal contrast in CESM is responsible for the earlier monsoon onset and excessive precipitation in September over the Yangtze River valley. Finer resolution in VR‐CESM, especially over the Tibetan Plateau (TP), appears to be a main factor in simulating better zonal thermal contrast and seasonal evolution of the EASM. The four critical timings of EASM (monsoon onset, withdrawal, peak, and duration) are better captured in VR‐CESM. 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subjects Advection
Climate models
Coefficients
Correlation coefficient
Correlation coefficients
Datasets
East Asian monsoon
East Asian summer monsoon
Evolution
Global climate
Global climate models
low‐level circulation
Modelling
Moisture effects
Monsoon onset
Monsoon precipitation
Monsoons
Precipitation
Resolution
River valleys
seasonal evolution
Simulation
Summer
Summer monsoon
thermal contrast
VR‐CESM
Wind
title Advantages of a variable‐resolution global climate model in reproducing the seasonal evolution of East Asian summer monsoon
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