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台风贝碧嘉(1816)外围云系结构与降水特征

毛志远 付丹红 黄彦彬 李光伟 敖杰 蔡杏富

毛志远, 付丹红, 黄彦彬, 等. 台风贝碧嘉(1816)外围云系结构与降水特征. 应用气象学报, 2022, 33(5): 604-616. DOI:  10.11898/1001-7313.20220508..
引用本文: 毛志远, 付丹红, 黄彦彬, 等. 台风贝碧嘉(1816)外围云系结构与降水特征. 应用气象学报, 2022, 33(5): 604-616. DOI:  10.11898/1001-7313.20220508.
Mao Zhiyuan, Fu Danhong, Huang Yanbin, et al. Peripheral cloud system structure and precipitation characteristics of Typhoon Bebinca(1816). J Appl Meteor Sci, 2022, 33(5): 604-616. DOI:  10.11898/1001-7313.20220508.
Citation: Mao Zhiyuan, Fu Danhong, Huang Yanbin, et al. Peripheral cloud system structure and precipitation characteristics of Typhoon Bebinca(1816). J Appl Meteor Sci, 2022, 33(5): 604-616. DOI:  10.11898/1001-7313.20220508.

台风贝碧嘉(1816)外围云系结构与降水特征

DOI: 10.11898/1001-7313.20220508
资助项目: 

国家自然科学基金项目 41865009

海南省自然科学基金项目 122QN424

海南省自然科学基金项目 420RC754

海南省自然科学基金项目 421QN372

海南省气象局项目 hnqxSJ202121

详细信息
    通信作者:

    黄彦彬, 邮箱:yanbinhuang@139.com

Peripheral Cloud System Structure and Precipitation Characteristics of Typhoon Bebinca(1816)

  • 摘要: 选取海南省海口站和屯昌站对比分析台风贝碧嘉(1816)外围云系结构和降水特征。结果表明:台风贝碧嘉(1816)影响海南岛期间,随着降水云系的发展,海口地区对流性云系发展加强,屯昌地区表现为层状云降水,两个站点雨滴谱特征存在一定的差异,海口站和屯昌站的降水均以直径小于1 mm的雨滴为主,其中屯昌站直径1~3 mm的雨滴对雨强的贡献最大;海口站雨滴数浓度随雨滴直径增大而减小,但对雨强的贡献随之增大,直径大于3 mm的雨滴对总雨强的贡献达到56.61%;海口站的特征参量曲线在时间上分布不均,表现为阵性强降水,而屯昌站的特征参量曲线起伏不大,降水比海口站小且均匀、连续;在雨滴谱演变上,海口站始终保持单峰型,屯昌站以单峰为主伴随多峰出现,当雨强增大时,两站直径1 mm范围内的雨滴数浓度随之增加,谱型迅速拓宽,大粒径雨滴出现且增多,其中海口站直径3 mm以上的雨滴端增幅更明显;两个站点雨滴谱符合Gamma分布,形状参数和斜率参数满足二项式关系。
  • 图  1  2018年8月14日00:00—15日00:00(a)和15日00:00—16日00:00(b)海南岛累积雨量

    Fig. 1  Cumulative precipitation in Hainan Island from 0000 BT 14 Aug to 0000 BT 15 Aug(a) and from 0000 BT 15 Aug to 0000 BT 16 Aug(b) in 2018

    图  2  2018年8月14日00:00—16日00:00海口站和屯昌站逐小时雨强

    Fig. 2  Hourly precipitation at Haikou and Tunchang stations from 0000 BT 14 Aug to 0000 BT 16 Aug in 2018

    图  3  2018年8月14日22:09—16日00:35台风贝碧嘉(1816)组合反射率因子

    Fig. 3  Radar composite reflectivity factor of Typhoon Bebinca(1816) from 2209 BT 14 Aug to 0035 BT 16 Aug in 2018

    图  4  2018年8月15日海口站和屯昌站雨滴总数浓度、雨强、雨滴最大直径、雨滴平均直径和雨滴谱

    Fig. 4  Total number raindrop concentration, rain intensity, randrop maximum diameter, raindrop mean diameter and raindrop size distribution at Haikou and Tunchang stations on 15 Aug 2018

    图  5  降水过程雨滴平均谱

    Fig. 5  Average raindrop size distribution

    图  6  不同等级雨强(I,单位:mm·h-1) 下的降水平均谱

    Fig. 6  Average raindrop size distribution under different rainfall intensity (I, unit:mm·h-1)

    图  7  各档直径雨滴对总数浓度和总雨强的贡献

    Fig. 7  Contribution of raindrops at different diameters for total number concentration and total rainfall intensity

    图  8  平均谱及Gamma函数拟合

    Fig. 8  Average raindrop size distribution and Gamma fit results

    图  9  λμ的关系分布

    Fig. 9  Distribution of λ and μ

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出版历程
  • 收稿日期:  2020-03-17
  • 修回日期:  2022-06-17
  • 刊出日期:  2022-09-15

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