Wheeler and Hendon 2004 The MJO 7N Equator SKa NCAR S-PolKa Radar.

Slides:

Advertisements

Similar presentations

Chapter 4 Convective Dynamics 4. 5

Advertisements

Squall Lines Loosely defined: A line of either ordinary cells or supercells of finite length (10- hundreds of km) that may contain a stratiform rain region.

The Convective Cloud Population during the Buildup of the Madden- Julian Oscillation AGU Fall Meeting, San Francisco, 7 December 2011 R. Houze, S. Brodzik,

Severe Convection and Mesoscale Convective Systems R. A. Houze Lecture, Summer School on Severe and Convective Weather, Nanjing, 11 July 2011.

Seminar, National Taiwan University, Taipei, 15 April 2011 Robert Houze University of Washington The tropical convective cloud population.

Robert A. Houze, Jr., Darren C. Wilton, and Bradley F. Smull University of Washington Robert A. Houze, Jr., Darren C. Wilton, and Bradley F. Smull University.

Mesoscale Convective Systems: Recent Observational and Diagnostic Studies Robert Houze Department of Atmospheric Sciences University of Washington 10 th.

Cirrus Production by a Mesoscale Convective System Sampled During TWP-ICE: Analysis via Water Budget Equations Jasmine Cetrone and Robert Houze University.

ASR Science Team Meeting, Bethesda, MD, 17 March 2010 R. Houze, C. Long, S. Medina, C. Zhang AMIE/CINDY/DYNAMO: Observations of the Madden-Julian Oscillation.

Convective Clouds Lecture Sequence Basic convective cloud types

Hector simulation We found simulation largely depending on: Model initialization scheme Lateral boundary conditions Physical processes represented in the.

Convective Weather Thunderstorms Lightning Tornadoes… …and more.

The Tropical Cloud Population R. A. Houze Lecture, Indian Institute of Tropical Meteorology, Pune, 9 August 2010.

Schumacher and Houze (2006) This Lecture: Review of Schumacher and Houze, 2006: Stratiform precipitation over sub- Saharan Africa and the Tropical.

Origins of MJO in central, equatorial Indian Ocean Mechanisms for initiation not well understood MJO affects: Monsoons (Onset and Intensity) TC activity.

Cirrus Production by Tropical Mesoscale Convective Systems Jasmine Cetrone and Robert Houze 8 February 2008.

Mesoscale Convective Systems Robert Houze Department of Atmospheric Sciences University of Washington Nebraska Kansas Oklahoma Arkansas.

DYNAMO Planning Meeting, Seattle, 6 July 2010 R. Houze DYNAMO Radar Plan.

2.6 Mesoscale Convective Systems Tropics are dominated by MCSs Consist of an amalgamation of individual clouds that form one coherent system – have convective.

Cirrus Production by Tropical Mesoscale Convective Systems Jasmine Cetrone and Robert Houze University of Washington Motivation Atmospheric heating by.

The tropical convective cloud population Peking University Seminar, Beijing, 4 July 2011 Robert Houze University of Washington.

Multi-sensor Analysis of Tropical Mesoscale Convective Systems Jian Yuan and R. A. Houze [J. Clim., J. Atmos. Sci.] NASA A-Train Symposium, New Orleans,

Diurnal Variability of Deep Tropical Convection R. A. Houze Lecture, Summer School on Severe and Convective Weather, Nanjing, July 2011.

Diurnal Variability of Deep Tropical Convection R. A. Houze Lecture, Indian Institute of Tropical Meteorology, Pune, 12 August 2010.

Mesoscale Convective Systems: Recent Observational and Diagnostic Studies Robert Houze Department of Atmospheric Sciences University of Washington.

Mesoscale Convective System Heating and Momentum Feedbacks R. Houze NCAR 10 July 2006.

Characteristics of Isolated Convective Storms Meteorology 515/815 Spring 2006 Christopher Meherin.

Orographic triggering and mesoscale organization of extreme storms in subtropical South America Kristen Lani Rasmussen Robert A. Houze, Jr. ICAM 2013,

AGU Annual Meeting, San Francisco, 11 December 2013.

MJO is: A convective disturbance that initiates over the tropical Indian Ocean and propagates eastward. MJO “wave” can propagate around the entire tropics.

The MJO Precipitating Cloud Population over the Central Indian Ocean as seen by the TRMM PR Hannah C. Barnes Robert A. Houze, Jr. University of Washington.

The mesoscale organization and dynamics of extreme convection in subtropical South America Kristen Lani Rasmussen Robert A. Houze, Jr., Anil Kumar 2013.

Thunderstorms and Tornadoes Last Lecture: We looked at severe weather events in the lower latitudes Principal weather event is the formation and movement.

A Conceptual Model for the Hydrometeor Structure of Mesoscale Convective Systems during the MJO Active Stage Hannah C. Barnes Robert A. Houze, Jr. University.

A Conceptual Model for the Hydrometeor Structure of Mesoscale Convective Systems during the MJO Active Stage Hannah C. Barnes Robert A. Houze, Jr. University.

Severe Convection and Mesoscale Convective Systems R. A. Houze Lecture, Indian Institute of Tropical Meteorology, Pune, 5 August 2010.

Tropical Convection: A Half Century Quest for Understanding Bjerknes Memorial Lecture, AGU, San Francisco, 4 December 2012 Robert Houze University of Washington.

25N 30N 65E75E65E75E65E75E Height (km) 8 Distance (km)

The MJO Cloud Population over the Indian Ocean

Joanna Futyan and Tony DelGenio GIST 25, Exeter, 24 th October 2006 The Evolution of Convective Systems over Africa and the Tropical Atlantic.

Funded by NSF –Grant AGS Conceptual Model of Mesoscale Convective Systems (MCSs) ConvectiveStratiform TOGA COARE: 3D, layer airflow Kingsmill.

Image structures: rain shafts, cold pools, gusts Separate rain fall velocity from air velocity – turbulence retrieval– microphysical retrieval Diurnal.

MJO Insights from the S-PolKa radar in DYNAMO Robert A. Houze, Jr. H. C. Barnes, S. W. Powell, A. K. Rowe, M. Zuluaga University of Washington Symposium.

Cloud structure and organization under suppressed conditions during DYNAMO/AMIE/CINDY2011 Angela Rowe and Robert Houze, Jr. University of Washington 31.

Orographic Precipitation in Potentially Unstable Alpine Storms: MAP IOPs 2b, 3, and 5 Socorro Medina and Robert A. Houze.

Angela Rowe and Robert Houze, Jr. University of Washington 2015 US-Taiwan Extreme Precipitation and Weather Workshop Taipei, Taiwan 29 May 2015 Microphysical.

Dual-pol obs in NW Environment B. Dolan and S. Rutledge OLYMPEX planning meeting Seattle, 22 January 2015.

The Convective Cloud Population of the Madden- Julian Oscillation: Early Results from DYNAMO Int. Conf. on Opportunities and Challenges in Monsoon Prediction.

Kinematic, Microphysical, and Precipitation Characteristics of MCSs in TRMM-LBA Robert Cifelli, Walter Petersen, Lawrence Carey, and Steven A. Rutledge.

Floods in Pakistan and India 2010 Robert A. Houze, Jr. with S. Medina, U. Romatschke, K. Rasmussen, S. Brodzik, D. Niyogi, and A. Kumar Robert A. Houze,

Cheng-Zhong Zhang and Hiroshi Uyeda Hydroshperic Atmospheric Research Center, Nagoya University 1 November 2006 in Boulder, Colorado Possible Mechanism.

Global Distribution of Different Forms of Convection as Seen by TRMM Robert A. Houze, Jr. University of Washington with: K. L. Rasmussen, M. D. Zuluaga,

Angela Rowe and Robert Houze, Jr. University of Washington ASR Fall Working Groups AMIE/MJO Breakout November 2013 Rockville, MD.

Angela Rowe Radar Breakout Session DYNAMO Workshop, Kona, Hawaii 5 March 2013.

Impact of Cloud Microphysics on the Development of Trailing Stratiform Precipitation in a Simulated Squall Line: Comparison of One- and Two-Moment Schemes.

Multisensor Investigation of Deep Convection AGU, San Francisco, 5 December 2012 Robert A. Houze, Jr., & Jian Yuan University of Washington.

Megan Chaplin UW Department of Atmospheric Sciences Pacific Northwest Weather Workshop March 4, 2016 Orographic enhancement of precipitation as observed.

Rosenstial School of Marine and Atmospheric Science

EASC 11 Forecasting, Weather Maps, and Severe Storms Forecasting

Hannah C. Barnes, Robert A. Houze, Jr., and Manuel D. Zuluaga

2.5 Mesoscale Convective Systems

The Variable Structure of Convection at Low Latitudes

M. D. Zuluaga and R. A. Houze, Jr. University of Washington

MJO Modulation of Lightning in Mesoscale Convective Systems

Microphysics of 2-Day Rain Events During the Active Stage

Tong Zhu and Da-Lin Zhang 2006:J. Atmos. Sci.,63,

Ming-Jen Yang and Robert A. House Jr. Mon. Wea. Rev., 123,

Braun, S. A., 2006: High-Resolution Simulation of Hurricane Bonnie (1998). Part II: Water Budget. J. Atmos. Sci., 63, Gamache, J. F., R. A. Houze.

D. C. Stolz, S. A. Rutledge, J. R. Pierce, S. C. van den Heever 2017

Presentation transcript:

Wheeler and Hendon 2004 The MJO

7N Equator

SKa NCAR S-PolKa Radar

Satellite Global models Soundings Other island radars Ship data Ship radars Aircraft data S-PolKa radar NCAR radar processor UW server UW workstations Daily Science Summaries NCAR field catalog Project Data Flow LIghtning

Radar experiment goal  Characteristics and evolution of the MJO cloud population in the region where the disturbance builds up Addu Atoll

Supp. Active Lull Rain over area scanned by S-PolKa

Suppressed condition echoes

Supp. Active Lull

Suppressed phases: Lines of non- precipitating clouds

Suppressed phases: The “worm echo”

Slightly active moist layer Clouds building at cold pool boundaries

Slightly active moist layer Clouds building at cold pool boundaries

Cold pool boundaries seen in differential reflectivity (ZDR) Birds? Dragonflies? ???

Birds caught on camera

graupel small ice large non-melting ice heavy rain melting ice Moderate cumulonimbus begin to grow upscale Doppler velocity Hydrometeor type

Supp. Active Lull

October 16

Refl.Rain Conv. Strat. October 16

5 km 10 km Intense melting layer melting snow graupel 50 dBZ!

Active phase few days later Convection feeding into a large MCS

Biggest MCS of first active phase: weak unidirectional shear

Supp. Active Lull

Giant Rings of Convection Larger than mesoscale organization of deep convection

Squall line in late active phase westerlies Doppler velocity Hydrometeor type

Supp. Active Lull

Suppressed condition clouds

Supp. Active Lull

Supp. Active Lull

Westerly Surges November October Larger than mesoscale organization of deep convection

Supp. Active Lull

Long arc line

Long arc line segment on radar

Squall line in the strong westerlies

Weak stratiform in the strong westerlies

Stratiform Rain Fraction S-PolKa S-band Stratiform Rain Fraction

Supp. Active Lull

The most robust squall line in the strong westerlies… …only moderate stratiform …robust momentum transport

Supp. Active Lull

Summary of MJO cloud population characteristics & evolution seen by the S-PolKa radar  Humidity gradient layers monitored & measured  Cloud lines dominate in highly suppressed period  Cold pools are first stage of convective population  Graupel & other ice lofted & input into stratiform regions  Convection enhanced inside stratiform regions  MCS development strongest in weak shear  Shear inhibits stratiform region formation  Westerlies organize convection on larger than mesoscale  Squall lines form in westerlies at back of active zone  Squall lines transport momemtum downward

End This research is supported by NSF grant ATM AGS , DOE grant DE- SC /ER-64752, and NASA grants NNX10AM28G and NNX10AH70G