Observed Relationships between Cloud Vertical Structure and Convective Aggregation over Tropical Ocean

Using the satellite-infrared-based Simple Convective Aggregation Index (SCAI) to determine the degree of aggregation, 5 years of CloudSat–CALIPSO cloud profiles are composited at a spatial scale of 10 degrees to study the relationship between cloud vertical structure and aggregation. For a given lar...

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Bibliographic Details
Published inJournal of climate Vol. 30; no. 6; pp. 2187 - 2207
Main Authors Stein, T. H. M., Holloway, C. E., Tobin, I., Bony, S.
Format Journal Article
LanguageEnglish
Published Boston American Meteorological Society 15.03.2017
Subjects
Agglomeration
Aggregation
Anvil clouds
Atmosphere
Atmospheric precipitations
Brightness
Brightness temperature
Cirrus clouds
Climate
Cloud cover
Cloud distribution
Cloudiness
Clouds
Continental interfaces, environment
Convection
Efficiency
General circulation models
Humidity
Hydrology
Hypotheses
Levels
Lidar
Mean precipitation
Ocean, Atmosphere
Precipitation
Precipitation rate
Profiles
Rain
Rainfall
Satellites
Sciences of the Universe
Sea surface
Sea surface temperature
Spatial distribution
Surface temperature
Temperature effects
Tropical climate
Vertical motion
Vertical profiles
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Summary:Using the satellite-infrared-based Simple Convective Aggregation Index (SCAI) to determine the degree of aggregation, 5 years of CloudSat–CALIPSO cloud profiles are composited at a spatial scale of 10 degrees to study the relationship between cloud vertical structure and aggregation. For a given large-scale vertical motion and domain-averaged precipitation rate, there is a large decrease in anvil cloud (and in cloudiness as a whole) and an increase in clear sky and low cloud as aggregation increases. The changes in thick anvil cloud are proportional to the changes in total areal cover of brightness temperatures below 240K [cold cloud area (CCA)], which is negatively correlated with SCAI. Optically thin anvil cover decreases significantly when aggregation increases, even for a fixed CCA, supporting previous findings of a higher precipitation efficiency for aggregated convection. Cirrus, congestus, and midlevel clouds do not display a consistent relationship with the degree of aggregation. Lidar-observed low-level cloud cover (where the lidar is not attenuated) is presented herein as the best estimate of the true low-level cloud cover, and it is shown that it increases as aggregation increases. Qualitatively, the relationships between cloud distribution and SCAI do not change with sea surface temperature, while cirrus clouds are more abundant and low-level clouds less at higher sea surface temperatures. For the observed regimes, the vertical cloud profile varies more evidently with SCAI than with mean precipitation rate. These results confirm that convective scenes with similar vertical motion and rainfall can be associated with vastly different cloudiness (both high and low cloud) and humidity depending on the degree of convective aggregation.
ISSN:0894-8755
1520-0442
DOI:10.1175/jcli-d-16-0125.1