Observing Possible Thermodynamic Controls on Tropical Marine Rainfall in Moist Environments

Radar and rawinsonde data from four ground-based observing stations in the tropical Indo-Pacific warm pool were used to identify possible associations of environmental state variables and their vertical profiles with radar-derived rain rate inside a mesoscale radar domain when the column-integrated...

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Veröffentlicht in:	Journal of the atmospheric sciences 2019-12, Vol.76 (12), p.3737-3751
1. Verfasser:	Powell, Scott W.
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Sprache:	eng
Schlagworte:	Atmospheric boundary layer Atmospheric precipitations Convection Convective rainfall Echoes Ground stations Ground-based observation Humidity Lapse rate Life cycle Life cycles Oceans Precipitation Profiles Radar Radar data Rain Rainfall Rawinsondes Relative humidity State variable Tropical climate Updraft Vertical air currents Vertical profiles
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description	Radar and rawinsonde data from four ground-based observing stations in the tropical Indo-Pacific warm pool were used to identify possible associations of environmental state variables and their vertical profiles with radar-derived rain rate inside a mesoscale radar domain when the column-integrated relative humidity (CRH) exceeds 80%. At CRH exceeding 80%, a wide range—from near 0 to ~50 mm day−1—in rain rate is observed; therefore, tropospheric moisture was a necessary but insufficient condition for deep convection. This study seeks to identify possible factors that inhibit rainfall when the atmosphere is sufficiently moist to support large precipitation rates. The domain-mean rain rate was highly sensitive to the areal coverage of intense, convective rainfall that occurs. There were two fundamentally different instances in which convective area was low. One was when the radar domain is primarily occupied by weakly precipitating, stratiform echoes. The other was when the radar domain contained almost no precipitating echoes of any type. While the former was dependent upon the stage of the convective life cycle seen by radar, the latter was probably dependent upon the convective environment. Areal coverage of convective echoes was largely determined by the number of individual convective echoes rather than their sizes, so changes in the clear-air environment of updrafts might have governed how many updrafts grew into deep cumulonimbi. The most likely environmental influence on convective rainfall identified using rawinsonde data was 900–700-hPa lapse rate; however, processes occurring on spatial scales smaller than a radar domain were probably also important but not investigated.
doi_str_mv	10.1175/JAS-D-19-0144.1
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At CRH exceeding 80%, a wide range—from near 0 to ~50 mm day−1—in rain rate is observed; therefore, tropospheric moisture was a necessary but insufficient condition for deep convection. This study seeks to identify possible factors that inhibit rainfall when the atmosphere is sufficiently moist to support large precipitation rates. The domain-mean rain rate was highly sensitive to the areal coverage of intense, convective rainfall that occurs. There were two fundamentally different instances in which convective area was low. One was when the radar domain is primarily occupied by weakly precipitating, stratiform echoes. The other was when the radar domain contained almost no precipitating echoes of any type. While the former was dependent upon the stage of the convective life cycle seen by radar, the latter was probably dependent upon the convective environment. 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At CRH exceeding 80%, a wide range—from near 0 to ~50 mm day−1—in rain rate is observed; therefore, tropospheric moisture was a necessary but insufficient condition for deep convection. This study seeks to identify possible factors that inhibit rainfall when the atmosphere is sufficiently moist to support large precipitation rates. The domain-mean rain rate was highly sensitive to the areal coverage of intense, convective rainfall that occurs. There were two fundamentally different instances in which convective area was low. One was when the radar domain is primarily occupied by weakly precipitating, stratiform echoes. The other was when the radar domain contained almost no precipitating echoes of any type. While the former was dependent upon the stage of the convective life cycle seen by radar, the latter was probably dependent upon the convective environment. 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Possible Thermodynamic Controls on Tropical Marine Rainfall in Moist Environments</title><author>Powell, Scott W.</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c356t-96346821aa878d7b18662269b82e7bf3bd70f9241c81c1ce91789310336e15ce3</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2019</creationdate><topic>Atmospheric boundary layer</topic><topic>Atmospheric precipitations</topic><topic>Convection</topic><topic>Convective rainfall</topic><topic>Echoes</topic><topic>Ground stations</topic><topic>Ground-based observation</topic><topic>Humidity</topic><topic>Lapse rate</topic><topic>Life cycle</topic><topic>Life cycles</topic><topic>Oceans</topic><topic>Precipitation</topic><topic>Profiles</topic><topic>Radar</topic><topic>Radar data</topic><topic>Rain</topic><topic>Rainfall</topic><topic>Rawinsondes</topic><topic>Relative humidity</topic><topic>State variable</topic><topic>Tropical 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subjects	Atmospheric boundary layer Atmospheric precipitations Convection Convective rainfall Echoes Ground stations Ground-based observation Humidity Lapse rate Life cycle Life cycles Oceans Precipitation Profiles Radar Radar data Rain Rainfall Rawinsondes Relative humidity State variable Tropical climate Updraft Vertical air currents Vertical profiles
title	Observing Possible Thermodynamic Controls on Tropical Marine Rainfall in Moist Environments
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