西南亚马逊地区低空云的日循环和热带对流边界层

C. Strong, J. Fuentes, M. Garstang, A. Betts
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引用次数: 25

摘要

在亚马逊河西南地区的雨季,白天从大气混合层向深层大气的水输送取决于云的数量和类型以及天气尺度的速度场。对1999年巴西大尺度生物圈-大气(TRMM-LBA)野外活动的热带降雨测量任务组成部分观测到的两种主要气流形式的云、对流条件和亚云层特性之间的相互作用进行了估计。在白天,云层和亚云层通过辐射、对流和降水过程耦合。云层和亚云层的性质随对流层低层气流的东西风对流影响的不同而变化。对复合云周期影响最显著的是持续的对流层低层流动,这产生了强对流云增长,几乎没有低层层状云,入射太阳辐照度的累积衰减最小(25%),日间混合层快速增长(100 mh 1),边界层干燥(0.22 g kg 1 h 1),高对流速度(1.5 m s 1),高地表浮力通量(200 Wm 2)。高潜热通量(600 wm2)进入云层。相比之下,持续的西风对流较少,表现出强烈的低层层状云(0.9云量)的早晨存在,入射太阳辐照度的累积衰减更大(47%),混合层增长较慢(50 mh 1),混合层略有湿润趋势,低层积雨云周期的峰值延迟(2000年与1700 UTC)。本文报告的结果表明,数值模式在估计水汽输送到云层时需要考虑云的数量和类型。
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Daytime Cycle of Low-Level Clouds and the Tropical Convective Boundary Layer in Southwestern Amazonia
During the wet season in the southwestern Amazon region, daytime water transport out of the atmospheric mixed layer into the deeper atmosphere is shown to depend upon cloud amounts and types and synoptic-scale velocity fields. Interactions among clouds, convective conditions, and subcloud-layer properties were estimated for two dominant flow regimes observed during the 1999 Tropical Rainfall Measuring Mission component of the Brazilian Large-Scale Biosphere–Atmosphere (TRMM-LBA) field campaign. During daytime the cloud and subcloud layers were coupled by radiative, convective, and precipitation processes. The properties of cloud and subcloud layers varied according to the different convective influences of easterly versus westerly lower-tropospheric flows. The most pronounced flow-regime effects on composite cloud cycles occurred under persistent lower-tropospheric flows, which produced strong convective cloud growth with a near absence of low-level stratiform clouds, minimal cumulative attenuation of incoming solar irradiance (25%), rapid daytime mixed-layer growth ( 100 mh 1 ), and boundary layer drying (0.22 g kg 1 h 1 ), high convective velocities (1.5 m s 1 ), high surface buoyancy flux ( 200 Wm 2 ), and high latent heat flux (600 W m 2 ) into cloud layer. In contrast, persistent westerly flows were less convective, showing a strong morning presence of low-level stratiform genera (0.9 cloud amount), greater cumulative attenuation of incoming solar irradiance (47%), slower mixed-layer growth ( 50 mh 1 ) with a slight tendency for mixed-layer moistening, and a delayed peak in the low-level cumuliform cloud cycle (2000 versus 1700 UTC). The results reported in this article indicate that numerical models need to account for cloud amounts and types when estimating water vapor transport to the cloud layer.
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