2001-2020 年雨季青藏高原上空的孤立深层对流

IF 2.3 4区 地球科学 Q3 METEOROLOGY & ATMOSPHERIC SCIENCES
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引用次数: 0

摘要

青藏高原因其独特的热动力强迫而成为对流系统的多发区。本研究调查了 2001-2020 年间雨季(6-9 月)青藏高原上的孤立深对流(IDCs),与中尺度对流系统(MCSs)相比,IDCs 的时空规模较小。作者使用了全球降水测量任务的卫星降水和亮度温度观测数据。结果表明,IDC 主要集中在南部大陆架。每个雨季的 IDC 数量从南部热带降雨带的约 140 个减少到北部热带降雨带的约 10 个,平均为 54.2 个。IDC 的开始时间呈现出明显的昼夜周期,高峰期在 1400-1500 LST,低谷期在 0900-1000 LST。大多数 IDC 持续时间不超过 5 小时,一半以上的 IDC 仅出现 1 小时。IDC 的冷云面积一般为 7422.9 平方公里,其中降水面积约占 65%。IDC 的面积越大,包含的强降水就越多。IDC 约占整个热带降水量的 20%-30%,约占极端降水量的 30%-40%,其中 7 月和 8 月的比例大于 6 月和 9 月。从空间分布来看,与周边平原地区相比,IDC 对大洋洲保护区总降水量和极端降水量的贡献都更大。TP上的IDC占比大于MCS,表明IDC在该区域的重要作用。摘要本文利用卫星观测资料,研究了2001-2020年雨季 (6-9月) 青藏高原上孤立深对流 (Isolated deep convections, IDCs) 的气候特征。IDCs定义为比中尺度对流系统 (Mesoscale convective systems, MCSs) 时空尺度小的对流。结果显示, 每年雨季青藏高原上平均的idc 数量为 54.2 个, 主要分布在高原的南部。IDCs的初始时刻呈现明显的日循环, 在下午14-15时为峰值, 在上午9-10时为谷值。大部分 IDCs 持续时间在 5 小时以内, 超过一半的 IDCs 仅持续 1 小时。IDCs的冷云平均面积约为7422.9km2,其中包含65%的降水面积。IDC的冷云平均面积约为7422.9km2, 其中包含65%的降水面积。IDCs对青藏高原总降水的贡献约为20%-30%, 对极端降水的贡献约为30%-40%, 在7月和8月的占比大于6月和9月。在空间分布方面,青藏高原上IDCs对总降水和极端降水的贡献大于周围平原地区。青藏高原上 IDCs 对总降水和极端降水的贡献大于周围平原地区。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Isolated deep convections over the Tibetan Plateau in the rainy season during 2001–2020

Isolated deep convections over the Tibetan Plateau in the rainy season during 2001–2020

The Tibetan Plateau (TP) is a prevalent region for convection systems due to its unique thermodynamic forcing. This study investigated isolated deep convections (IDCs), which have a smaller spatial and temporal size than mesoscale convective systems (MCSs), over the TP in the rainy season (June–September) during 2001–2020. The authors used satellite precipitation and brightness temperature observations from the Global Precipitation Measurement mission. Results show that IDCs mainly concentrate over the southern TP. The IDC number per rainy season decreases from around 140 over the southern TP to around 10 over the northern TP, with an average 54.2. The initiation time of IDCs exhibits an obvious diurnal cycle, with the peak at 1400–1500 LST and the valley at 0900–1000 LST. Most IDCs last less than five hours and more than half appear for only one hour. IDCs generally have a cold cloud area of 7422.9 km2, containing a precipitation area of approximately 65%. The larger the IDC, the larger the fraction of intense precipitation it contains. IDCs contribute approximately 20%–30% to total precipitation and approximately 30%–40% to extreme precipitation over the TP, with a larger percentage in July and August than in June and September. In terms of spatial distribution, IDCs contribute more to both total precipitation and extreme precipitation over the TP compared to the surrounding plain regions. IDCs over the TP account for a larger fraction than MCSs, indicating the important role of IDCs over the region.

摘要

本文利用卫星观测资料, 研究了2001–2020年雨季 (6–9月) 青藏高原上孤立深对流 (Isolated deep convections, IDCs) 的气候特征. IDCs定义为比中尺度对流系统 (Mesoscale convective systems, MCSs) 时空尺度小的对流. 结果显示, 每年雨季青藏高原上平均的IDC数量为54.2个, 主要分布在高原的南部. IDCs的初始时刻呈现明显的日循环, 在下午14–15时为峰值, 在上午9–10时为谷值. 大部分IDCs持续时间在5小时以内, 超过一半的IDCs仅持续1小时. IDCs的冷云平均面积约为7422.9km2, 其中包含65%的降水面积. IDC面积越大, 包含的强降水范围也越大. IDCs对青藏高原总降水的贡献约为20%–30%, 对极端降水贡献约为30%–40%, 在7月和8月的占比大于6月和9月. 在空间分布方面, 青藏高原上IDCs对总降水和极端降水的贡献大于周围平原地区. 青藏高原上IDCs对降水的贡献大于MCSs, 表明IDCs在该地区起着重要作用.

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来源期刊
Atmospheric and Oceanic Science Letters
Atmospheric and Oceanic Science Letters METEOROLOGY & ATMOSPHERIC SCIENCES-
CiteScore
4.20
自引率
8.70%
发文量
925
审稿时长
12 weeks
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