Evaluating E3SM Global Storm-Resolving Model Simulations of Deep Convection: Insights From DP-SCREAM During TRACER

IF 3.4 2区地球科学 Q2 METEOROLOGY & ATMOSPHERIC SCIENCES

Journal of Geophysical Research: Atmospheres Pub Date : 2025-10-18 DOI:10.1029/2025JD044113

Raymond Kwaku Twumasi Oware, Youtong Zheng, Peter Bogenschutz, Yunyan Zhang, Hsi-Yen Ma, Shaocheng Xie, Cheng Tao

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Abstract

Global Storm-Resolving Models (GSRMs) are becoming increasingly vital for advancing climate modeling and improving the prediction of extreme weather events. Houston, a coastal region frequently affected by deep convective storms, offers an ideal setting to evaluate the ability of GSRMs to simulate deep convection. This study assesses the performance of the Doubly Periodic Simple Cloud-Resolving E3SM (Energy Exascale Earth System Model) Atmosphere Model (DP-SCREAM) using observations from the TRacking Aerosol Convection interactions ExpeRiment (TRACER) campaign. DP-SCREAM effectively reproduces the diurnal cycles of clouds and precipitation, demonstrating much greater skill than the E3SM single column model. The DP-SCREAM is demonstrated to be applicable to coastal regions, partially due to the forcing data sets already capturing the influence of breezes. DP-SCREAM also replicates biases persistent in the global version of SCREAM: the underrepresentation of boundary layer shallow clouds, a lack of mid-level congestus clouds, and the popcorn convection, characterized by small and disorganized convective cells generating the strongest precipitation. To investigate these issues, two sensitivity experiments were conducted: increasing the mixing length and scaling up the buoyancy flux within the Simplified Higher Order Closure scheme. Increasing the mixing length improved mid-level congestus representation and reduced unrealistic early morning fog occurrence. Enhancing buoyancy flux only marginally improved the bias of underproduced big convective cells. An additional resolution sensitivity test at 0.5 km grid spacing demonstrated that a refined horizontal resolution alone is insufficient to resolve these biases.

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评估E3SM全球风暴解析模式对深层对流的模拟：来自DP-SCREAM在TRACER期间的见解

全球风暴分辨模式（GSRMs）在推进气候建模和改善极端天气事件预测方面变得越来越重要。休斯顿是一个经常受到深层对流风暴影响的沿海地区，为评估GSRMs模拟深层对流的能力提供了理想的环境。本研究利用跟踪气溶胶对流相互作用实验（TRACER）活动的观测结果评估了双周期简单云分辨E3SM（能量e级地球系统模型）大气模型（DP-SCREAM）的性能。DP-SCREAM有效地再现了云和降水的日循环，显示出比E3SM单柱模式更高的技巧。DP-SCREAM被证明适用于沿海地区，部分原因是强迫数据集已经捕获了微风的影响。DP-SCREAM也重复了全球版SCREAM中持续存在的偏差：边界层浅云的代表性不足，中层密集云的缺乏，以及爆米花对流，以小而无组织的对流细胞产生最强降水为特征。为了研究这些问题，在简化高阶闭合方案下进行了两个灵敏度实验：增加混合长度和增大浮力通量。增加混合长度改善了中层拥堵的表现，减少了不切实际的清晨雾的发生。增强浮力通量仅能略微改善产生不足的大对流单体的偏置。在0.5 km网格间距处进行的额外分辨率灵敏度测试表明，仅靠精细的水平分辨率不足以解决这些偏差。

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来源期刊

Journal of Geophysical Research: Atmospheres Earth and Planetary Sciences-Geophysics

CiteScore

7.30

自引率

11.40%

发文量

684

期刊介绍： JGR: Atmospheres publishes articles that advance and improve understanding of atmospheric properties and processes, including the interaction of the atmosphere with other components of the Earth system.