Multisensor analysis of a squall line in the Amazon Region

Mesoscale features of the 26 January 1999 squall line are described with measurements made during the field experiment in Rondônia, Brazil, in the wet season (WET) of the Amazon region (AMC) as part of the Large‐Scale Biosphere‐Atmosphere Experiment in the Amazon (LBA) and the Tropical Rainfall Meas...

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Veröffentlicht in:	Journal of Geophysical Research. D. Atmospheres 2002-10, Vol.107 (D20), p.LBA 52-1-LBA 52-12
Hauptverfasser:	Pereira Filho, Augusto J., Silva Dias, Maria A. F., Albrecht, Rachel I., Pereira, Luis G. P., Gandu, Adilson W., Massambani, Oswaldo, Tokay, Ali, Rutledge, Steve
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Sprache:	eng
Schlagworte:	Amazon cloud microphysics cold pool mesoscale dynamics remote sensing squall line
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container_end_page	LBA 52-12
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container_start_page	LBA 52-1
container_title	Journal of Geophysical Research. D. Atmospheres
container_volume	107
creator	Pereira Filho, Augusto J. Silva Dias, Maria A. F. Albrecht, Rachel I. Pereira, Luis G. P. Gandu, Adilson W. Massambani, Oswaldo Tokay, Ali Rutledge, Steve
description	Mesoscale features of the 26 January 1999 squall line are described with measurements made during the field experiment in Rondônia, Brazil, in the wet season (WET) of the Amazon region (AMC) as part of the Large‐Scale Biosphere‐Atmosphere Experiment in the Amazon (LBA) and the Tropical Rainfall Measurement Mission (TRMM); henceforth referred to as the WET AMC and TRMM‐LBA field experiment. The squall line moved through the experiment area from northeast to southwest with high rainfall rates in its leading edge and a poorly defined trailing stratiform precipitating area. Polarimetric and Doppler measurements from the Portable Polarimetric S‐band Radar (S‐POL) were analyzed in conjunction with surface and upper level data, satellite visible (VIS) and infrared (IR) measurements. These remote and local measurements of variables such as cloud spatial and temporal distribution, pressure, temperature, moisture, precipitation, and wind fields are consistent with each other as well as with similar mesoscale dynamics and thermodynamics features measured, analyzed, and modeled elsewhere [e.g., Rotunno et al., 1988; Garstang et al., 1994; Houze et al., 1990]. This tropical squall line is similar to its cousins in the midlatitudes with finer‐scale structural and dynamic features such as rotation and divergence. Results suggest that the cold pool has its origins in midlevels between 400 and 600 hPa from where evaporative cooling and drop‐dragging bring down colder air to the surface. The convective region is dominated by warm microphysics, while the stratiform region is dominated by cold microphysics. Moreover, both regions are characterized by monomodal drop spectra centered around 2.0 and 1.0 mm, respectively. Horizontal circulation associated with strong updrafts tends to increase cloud growth efficiency in the leading edge of the squall line.
doi_str_mv	10.1029/2000JD000305
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The squall line moved through the experiment area from northeast to southwest with high rainfall rates in its leading edge and a poorly defined trailing stratiform precipitating area. Polarimetric and Doppler measurements from the Portable Polarimetric S‐band Radar (S‐POL) were analyzed in conjunction with surface and upper level data, satellite visible (VIS) and infrared (IR) measurements. These remote and local measurements of variables such as cloud spatial and temporal distribution, pressure, temperature, moisture, precipitation, and wind fields are consistent with each other as well as with similar mesoscale dynamics and thermodynamics features measured, analyzed, and modeled elsewhere [e.g., Rotunno et al., 1988; Garstang et al., 1994; Houze et al., 1990]. This tropical squall line is similar to its cousins in the midlatitudes with finer‐scale structural and dynamic features such as rotation and divergence. Results suggest that the cold pool has its origins in midlevels between 400 and 600 hPa from where evaporative cooling and drop‐dragging bring down colder air to the surface. The convective region is dominated by warm microphysics, while the stratiform region is dominated by cold microphysics. Moreover, both regions are characterized by monomodal drop spectra centered around 2.0 and 1.0 mm, respectively. 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subjects	Amazon cloud microphysics cold pool mesoscale dynamics remote sensing squall line
title	Multisensor analysis of a squall line in the Amazon Region
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