Embed Size (px)
DESCRIPTION
Mesoscale Convective Systems in the Initiation of the MJO. Jian Yuan and Robert A. Houze University of Washington. CloudSat/CALIPSO Science Team Meeting Montreal, Quebec, Canada, 16 June 2011. The Madden-Julian Oscillation (MJO): Play important roles in weather and climate - PowerPoint PPT Presentation
Citation preview
Mesoscale Convective Systems in the Initiation of the MJO
Jian Yuan and Robert A. HouzeUniversity of Washington
CloudSat/CALIPSO Science Team Meeting Montreal, Quebec, Canada, 16 June 2011
The Madden-Julian Oscillation (MJO):
• Play important roles in weather and climate
• Current prediction skill, especially for the initial phase of MJO is very limited
• Cumulus parameterizations in GCMs is the primary limiting factor in MJO simulation and prediction.
(Zhang et al. 2010, DYNAMO)
(Courtesy of US CLIVAR MJO Working Group)
MJO initiation processes
Feedbacks between:
•Clouds•Radiative heating•Convection•Precipitation •Ocean
are a key to understanding the MJO.
Fundamental processes related to MCSs that are crucial to understand MJO:
•the diabatic heating structure•convective sensitivity to environmental moisture•cloud microphysics•convective organization
Courtesy of Zhang et al. 2009, DYNAMO After Stephens et al. 2004, “Humidistat Feedback”
MCSs including both raining and anvil components are identified using A-Train
instruments
Yuan and Houze 2010
MODIS TB11 + AMSR-E (Yuan and Houze 2010)
combined to find“cold centers” & “raining areas”
Use 260 K threshold
Locate 1st closed contour
Use 1 mm/h threshold for rain rate
Associate pixels with nearest cold center
Use 6 mm/h threshold for heavy rain
MCS Criteria (Yuan and Houze, 2010)
Systems whose largest raining cores have
• Area > 2000 km2
• Min TB11 ≤ 220 K
Must have one dominant core
• with intense cells, and• accounting for >70% rain area56% all tropical rain
MCSs are further divided to two groups :
1.Separated (40 % rain fall)
1.Connected (>=3 MCSs share the same rain feature, 16% rain fall)• Separated MCS: Frequently found over all
convective zones, especially continents
• Connected MCS: more organized convection, primarily found over warm ocean area
MODIS/AMSR-E/CloudSat
identifies MCSs obtains the global distribution of MCSs
investigates variability of MCSs in MJO
(EIO:-15-15oN;75-100oE; Composite of 8 phases; Wheeler and Hendon 2004)
More Connected MCSs observed in MJO
active phases
OLR
Deeper MCSs observed in pre-onset, initial and active phases
Low level Θe likely determines the Tb_min
(“hot tower” hypothesis)
Phase 1-3
Phase 5-7
Climatology of EIO:
•T150 hp ≈ 205 K
•Θe150 hp≈ 352.6 K
Moisture effects need to be better understood
Deeper MCSs
Deeper MCSs
Less MCSs; less
organized
More MCSs; more
organized
Summary and Conclusions
A-Train instruments make it possible to identify MCSs (raining + anvil components) globally
MJO pre-onset phase active phases over EIO:
Deeper MCSs & Warmer low level Θe (both)
Less More MCSs
Relatively Less More organized MCSs
Drier Moister middle troposphere
End
MJO activities viewed in OLR
MCSs Over the Whole Tropics: oceanic conditions favor larger systems
Smallest 25% (<12,000 km2)
Largest 25% (>40,000 km2)
“Superclusters”
