Characteristics of extreme hourly precipitation induced by tropical cyclones in Zhejiang, China: A comparative analysis based on two different datasets

IF 4.5 2区地球科学 Q1 METEOROLOGY & ATMOSPHERIC SCIENCES

Atmospheric Research Pub Date : 2024-09-30 DOI:10.1016/j.atmosres.2024.107712

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引用次数: 0

Abstract

This study investigates the characteristics of tropical cyclones (TCs) that cause extreme hourly precipitation (EXHP) in Zhejiang, China, using datasets from 67 national stations (Con-ST) and 1551 surface stations (All-ST), spanning 1973–2020 and 2011–2020, respectively. Our analysis revealed notable variations in the EXHP caused by individual TCs. The top 10 % of TCs contributed 37.2–38 % of the total TC-induced EXHP amount, while the bottom 50 % only accounted for 5.8–22.7 %. Using sparse stations may overestimate the impact of TCs causing EXHP in the lower to middle rankings. Long-term trend analysis suggested a consistent increase in TC-induced EXHP despite a decreasing trend in the number of TCs affecting Zhejiang. High-value EXHP centers tended to be concentrated in mountainous areas within 0–50 km from the coastline, where Con-ST stations are sparse and can significantly underestimate EXHP. The maximum amount of EXHP per TC increased logarithmically with the number of observation stations. In Zhejiang, EXHP predominantly occurred northeast of the TC centers (50.4–61.7 %) and within 500 km from the TC center (69.5–81.5 %). High-frequency EXHP centers exhibited a clockwise rotation with increasing distance from the TC center–a pattern resembling a “spiral rainband.” A key area where most EXHP in Zhejiang occurred when TC centers remained within this area was identified. The TC intensity within the key area was a key factor influencing EXHP occurrence in Zhejiang, whereas the duration of TC center residence within the key area and the distance of its movement were crucial predictors of significant EXHP occurrence. The analysis of large-scale environmental fields revealed that high-EXHP TCs are characterized by strong upper-level divergence, intense upward motion, and an expanded subtropical high. The southeasterly steering airflow drives these TCs northwestward, prolonging their impact on Zhejiang and resulting in significant moisture accumulation and EXHP.

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中国浙江热带气旋引发的极端小时降水特征：基于两种不同数据集的对比分析

本研究利用来自 67 个国家站（Con-ST）和 1551 个地面站（All-ST）的数据集，分别研究了 1973-2020 年和 2011-2020 年导致中国浙江极端小时降水量（EXHP）的热带气旋（TC）的特征。我们的分析表明，单个热带气旋造成的 EXHP 有显著差异。前10%的TC占TC引起的EXHP总量的37.2-38%，而后50%的TC仅占5.8-22.7%。使用稀疏站点可能会高估TC对中低层EXHP的影响。长期趋势分析表明，尽管影响浙江的TC数量呈减少趋势，但TC引起的EXHP持续增加。高值的EXHP中心往往集中在距离海岸线0-50公里内的山区，而这些地区的Con-ST站点稀少，会大大低估EXHP。每个 TC 的最大 EXHP 量随观测站点数量的增加而呈对数增长。在浙江，EXHP主要出现在TC中心的东北部（50.4-61.7%）和距TC中心500公里以内（69.5-81.5%）。高频EXHP中心呈现出顺时针旋转的趋势，与TC中心的距离越来越远，这种模式类似于 "螺旋雨带"。当TC中心停留在这一区域内时，浙江的大部分EXHP发生在这一关键区域。关键区域内的TC强度是影响浙江EXHP发生的关键因素，而TC中心在关键区域内停留的时间及其移动的距离则是预测EXHP显著发生的关键因素。大尺度环境场分析表明，高EXHP TC具有强烈的高层辐合、强烈的上升运动和副热带高压扩张的特征。东南方向的转向气流推动这些TC向西北方向移动，延长了对浙江的影响时间，导致大量水汽积聚和EXHP的发生。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Atmospheric Research 地学-气象与大气科学

CiteScore

9.40

自引率

10.90%

发文量

460

审稿时长

47 days

期刊介绍： The journal publishes scientific papers (research papers, review articles, letters and notes) dealing with the part of the atmosphere where meteorological events occur. Attention is given to all processes extending from the earth surface to the tropopause, but special emphasis continues to be devoted to the physics of clouds, mesoscale meteorology and air pollution, i.e. atmospheric aerosols; microphysical processes; cloud dynamics and thermodynamics; numerical simulation, climatology, climate change and weather modification.