An investigation on joint data assimilation of a radar network and ground-based profiling platforms for forecasting convective storms

IF 2.8 3区 地球科学 Q3 METEOROLOGY & ATMOSPHERIC SCIENCES
Zhaoyang Huo, Yubao Liu, Yueqin Shi, Baojun Chen, Hang Fan, Yang Li
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引用次数: 0

Abstract

A summer convective precipitation case occurring in eastern China on July 16-17, 2020, is selected to investigate the impact of joint assimilation of ground-based profiling platforms and weather radars on forecasting convective storms using observational system simulation experiments (OSSEs). The simulated profiling platforms include Doppler wind lidar (DWL), wind profiler (WP), and microwave radiometer (MWR). Results show that joint assimilation of WP and radar data produces a better analysis of convective dynamical structure than joint assimilation of DWL and radar data, since WP detects deeper layer winds. Joint assimilation of MWR and radar data enables rapid adjustment of temperature and humidity and thus, avoids the potential errors introduced by the latent heat term of the radar diabatic initialization in the early stage. Profiling observations in a horizontal spacing of 80 km provide fewer benefits for convective forecasting, while reducing the spacing to 40 km can dramatically improve model analysis and forecasts. Joint assimilation of multiple profiling observations in a 20 km horizontal spacing with radar data exhibits a beneficial synergistic effect and mitigates “the ramp-down issue” during the forecast stage. Assimilating profiling observations with an update interval less than 30 mins does not have as pronounced an effect on convective forecasts as horizontal spacing. Furthermore, assimilating profiling observations at a 20 km horizontal spacing can obtain accurate mesoscale background environment and forecast storms with an ability comparable to radar data assimilation. This work emphasizes the need to consider implementing a joint mesoscale detection system that incorporates weather radars and profiling observations for leveraging convective storm forecasting.
雷达网与地基剖面平台联合同化资料对对流风暴预报的研究
以2020年7月16日至17日发生在中国东部的夏季对流降水为例,利用观测系统模拟实验(OSSEs)研究了地面廓线平台和气象雷达联合同化对对流风暴预报的影响。模拟平台包括多普勒风激光雷达(DWL)、风廓线仪(WP)和微波辐射计(MWR)。结果表明,WP和雷达资料的联合同化比DWL和雷达资料的联合同化能更好地分析对流动力结构,因为WP探测的是更深层次的风。MWR和雷达资料的联合同化可以快速调整温度和湿度,从而避免了早期雷达非绝热初始化的潜热项带来的潜在误差。水平间距为80 km的剖面观测对对流预报的影响较小,而将水平间距减小到40 km则可以显著改善模式分析和预报。在20公里水平间距内,将多个剖面观测资料与雷达资料联合同化,显示出有益的协同效应,减轻了预报阶段的“下降问题”。同化更新间隔小于30分钟的剖面观测对对流预报的影响不如水平间距那么明显。此外,同化20 km水平间距的剖面观测资料可以获得精确的中尺度背景环境和预报风暴,其能力可与雷达资料同化相当。这项工作强调需要考虑实施一个联合中尺度探测系统,该系统将天气雷达和剖面观测结合起来,以利用对流风暴预报。
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来源期刊
Monthly Weather Review
Monthly Weather Review 地学-气象与大气科学
CiteScore
6.40
自引率
12.50%
发文量
186
审稿时长
3-6 weeks
期刊介绍: Monthly Weather Review (MWR) (ISSN: 0027-0644; eISSN: 1520-0493) publishes research relevant to the analysis and prediction of observed atmospheric circulations and physics, including technique development, data assimilation, model validation, and relevant case studies. This research includes numerical and data assimilation techniques that apply to the atmosphere and/or ocean environments. MWR also addresses phenomena having seasonal and subseasonal time scales.
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