秋台风 "曼胡特"（2018 年）在南海上空 10.5 天的模拟研究：微物理特征和潜热预算

IF 1.2 4区地球科学 Q4 METEOROLOGY & ATMOSPHERIC SCIENCES

Meteorologische Zeitschrift Pub Date : 2024-01-01 DOI:10.1127/metz/2024/1176

Zixi Ruan, Jiangnan Li, Fangzhou Li, Wenshi Lin

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引用次数: 0

摘要

本文利用天气研究和预报模式 4.1 版（WRFV4.1）对南海 10.5 天内的秋季超强台风 "芒克"（2018 年）进行了云解析模拟。评估了热带气旋（TC）路径和强度对行星边界层（PBL）和云微物理（MP）方案的敏感性。准正常尺度消除（QNSE）PBL 方案和 WRF 单矩 7 级（WSM7）MP 方案（QNSE-WSM7）的组合具有最佳性能。QNSE-WSM7 能够合理地再现降水量、降雨的时空分布特征。云量随着热带气旋的发展而增加，并在减弱阶段达到峰值。降水和冰雹随着 TC 的增强而增加，随着 TC 的减弱而减少。云水、雨水和云冰在发展阶段最少。在减弱阶段，积雪、谷雨和冰雹达到谷底。随着热气旋加强到成熟阶段，云水、雨水和云冰有所增加。云冰、谷雨和冰雹从成熟阶段减少到减弱阶段。水介质的峰值与垂直速度的峰值非常吻合。峰值位于对流层低层云壁的液体颗粒更接近热气旋中心。相反，峰值位于对流层较高处云壁的冰颗粒则离热气旋中心较远。最主要的云微观物理转换过程是雪、冰雹和冰砾的瞬时融化。前三个潜热释放过程分别是水汽凝结形成云水、水汽凝结形成降雨以及云冰吸附降雨。前三个潜热吸收过程分别是云水蒸发形成水蒸气、云冰被雨水吸附以及雨水蒸发形成水蒸气。雪、冰雹和冰砾的融化是形成雨滴的主要因素。

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Simulation Study on the Autumn Typhoon Mangkhut (2018) in 10.5 Days over the South China Sea: Microphysical Characteristics and latent heat budget

This paper presents a cloud-resolving simulation of the autumn Super Typhoon Mangkhut (2018) in 10.5 days in the South China Sea using the Weather Research and Forecasting Model Version 4.1 (WRFV4.1). The sensitivity of tropical cyclone (TC) track and intensity to the planetary boundary Layer (PBL) and cloud microphysics (MP) scheme was evaluated. A combination of Quasi-normal Scale Elimination (QNSE) PBL scheme and WRF Single Moment 7‑class (WSM7) MP scheme (QNSE-WSM7) had the best performances. QNSE-WSM7 could reasonably reproduce precipitation amounts, temporal and spatial distribution characteristics of rainfall. Cloud water increased as the TC developed and peaked at the weakening stage. Graupel and hail increased as the TC strengthened and reduced as the TC weakened. Cloud water, rain water, and cloud ice were the least in the development stage. Snow, graupel, and hail bottomed during the weakening stage. Cloud water, rain water, and cloud ice increased as the TC intensified to the mature stage. Cloud ice, graupel, and hail reduced from the mature stage to the weakening stage. The peaks of the hydrometeors corresponded well with the peaks of the vertical velocity. Liquid particles with peaks at the lower troposphere in the cloud wall were closer to the TC center. Conversely, ice particles with peaks at the higher troposphere in the cloud wall were found farther away from the TC center. The dominant cloud microphysical conversion processes were the instantaneous melting of snow, hail, and graupel. The top three latent heat release processes were the condensation of water vapor to form cloud water, condensation of water vapor to form rain, and accretion of rain by cloud ice. The top three latent heat absorption processes were the evaporation of cloud water to form water vapor, accretion of cloud ice by rain, and evaporation of rain to form water vapor. The melting of snow, hail, and graupel was the dominant contributor to the formation of raindrops.

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来源期刊

Meteorologische Zeitschrift 地学-气象与大气科学

CiteScore

2.80

自引率

8.30%

发文量

审稿时长

6-12 weeks

期刊介绍： Meteorologische Zeitschrift (Contributions to Atmospheric Sciences) accepts high-quality, English language, double peer-reviewed manuscripts on all aspects of observational, theoretical and computational research on the entire field of meteorology and atmospheric physics, including climatology. Manuscripts from applied sectors such as, e.g., Environmental Meteorology or Energy Meteorology are particularly welcome. Meteorologische Zeitschrift (Contributions to Atmospheric Sciences) represents a natural forum for the meteorological community of Central Europe and worldwide.