Thermodynamic Structure of Tropical Cyclones From Aircraft Reconnaissance Kay Shelton University at Albany/SUNY, Albany, New York.

Slides:

Advertisements

Similar presentations

Tropical Transition Climatology R. McTaggart-Cowan, L. F. Bosart, C. A. Davis and G. Deane.

Advertisements

Tropical Cyclone Intrinsic Variability & Predictability Gregory J. Hakim University of Washington 67th IHC/Tropical Cyclone Research Forum 6 March 2013.

Rappin et al. (2011) Paper Discussion Patrick Duran 1 of 22 Introduction Asymmetric Env.ConclusionsQuestionsSymmetric Env. The Impact of Outflow Environment.

Hurricanes and climate ATOC 4720 class22. Hurricanes Hurricanes intense rotational storm that develop in regions of very warm SST (typhoons in western.

Annual- and zonal-mean climate of the tropics (NCEP) Relative humidity [%] Temperature [degC] surface pressure [mb] equatorial trough subtropical high.

Structure and Evolution of rainfall in Numerically Simulated Landfalling Hurricanes Sytske Kimball, University of South Alabama, Mobile, AL Introduction.

Deanna Hence, Robert Houze and Stacy Brodzik University of Washington Introduction Methodology Eyewall—All Overpasses Rainbands—All Overpasses Changes.

Longwave Cloud Forcing Due to Tropical Cyclone Presence: August 1995 Cristy King.

CONVECTION IN TROPICAL CYCLONES John Molinari and David Vollaro University at Albany, SUNY Northeast Tropical Conference Rensselaerville, NY June 2009.

A Case Study of Hurricane Formation in Strong Shear: Claudette (2003) Kay Shelton University at Albany, SUNY.

Lectures on Hurricanes Chanh Q. Kieu Department of Atmospheric and Oceanic Science University of Maryland AOSC400, Fall 2008.

USE OF HS3 DATA TO UNDERSTAND THE TROPICAL CYCLONE OUTFLOW LAYER John Molinari, Kristen Corbosiero, Stephanie Stevenson, and Patrick Duran University at.

Principal Rainband of Hurricane Katrina as observed in RAINEX Anthony C. Didlake, Jr. 28 th Conference on Hurricanes and Tropical Meteorology April 29,

AOS101 Lecture 10. A severe thunderstorm is defined as a thunderstorm that produces - Hail of 1 inch diameter (in central US) or larger and/or wind gusts.

Chris Birchfield Atmospheric Sciences, Spanish minor.

The fear of the LORD is the beginning of wisdom 陳登舜 ATM NCU Group Meeting REFERENCE : Liu., H., J. Anderson, and Y.-H. Kuo, 2012: Improved analyses.

Benjamin A. Schenkel Lance F. Bosart, and Daniel Keyser University at Albany, State University of New York.

Sensitivity of Tropical Cyclone Inner-Core Size and Intensity to the Radial Distribution of Surface Entropy Flux Wang, Y., and Xu, 2010: Sensitivity of.

Detailed Observations of Five African Easterly Waves During NAMMA F. J. Schmidlin (NASA), B. J. Morrison (SSAI), E. T. Northam (SSAI), J. Gerlach (NASA)

Benjamin A. Schenkel University at Albany, State University of New York, and Robert E. Hart, The Florida State University 6th Northeast.

Results from Vaisala’s long range lightning detection network (LLDN) tropical cyclone studies Nicholas W. S. Demetriades Applications Manager, Meteorology.

Observed Inner-Core Structural Variability in Hurricane Dolly Yu-Fen Huang Hendricks E. A., B. d. Mcnoldy, and Wayne H. Schubert.

Lightning Outbreaks in the Eyewall MET 614 Seminar Antti Pessi.

Energy Production, Frictional Dissipation, and Maximum Intensity of a Numerically Simulated Tropical Cyclone 4/ 蘇炯瑞 Wang, Y., and J. Xu, 2010: Energy.

By: Michelle Tyson Department of Marine and Environmental Systems College of Engineering Florida Institute of Technology FP 2007 Source: University of.

How Small-Scale Turbulence Sets the Amplitude and Structure of Tropical Cyclones Kerry Emanuel PAOC.

Jorgensen, D. P., 1984a: Mesoscale and convective-scale characteristics of mature Hurricanes. Part I: General observations by research aircraft. J. Atmos.

The Centre for Australian Weather and Climate Research A partnership between CSIRO and the Bureau of Meteorology The Tropical Cyclone Boundary Layer 4:

Tropical Cyclones: Steady State Physics. Energy Production.

Hurricanes One of Natures most powerful and destructive storms.

1 Aircraft observations of the multiscale structure and evolution of rapidly intensifying tropical cyclones Robert Rogers 1, Paul Reasor 1, Jun Zhang 2,

Sensitivity of Tropical Cyclone Intensity to Ventilation in an Axisymmetric Model Brian Tang, and Kerry Emanuel J. Atmos. Sci., 69, 2394–2413.

Improved SFMR Surface Winds and Rain Rates Eric W. Uhlhorn NOAA/AOML/Hurricane Research Division Bradley W. Klotz University of Miami/RSMAS/CIMAS and HRD.

“It's tough to make predictions, especially about the future” HO fail all WEVER… HO fail all WEVER… “You can see a lot by looking” Yogi Berra High Pressure.

Idealized Tropical Cyclone Structure. Tropical Cyclone Extension of the Warm Core middle –level vortex to the surface. Inducement of Ekman pumping Non-linear.

2015 HS3 Science Team Meeting Ames Research Center, Moffett Field, CA.

Benjamin A. Schenkel University at Albany, State University of New York, and Robert E. Hart, The Florida State University 4 th.

Convective Oscillations in a Strongly Sheared Tropical Storm Jaclyn Frank and John Molinari The University at Albany, SUNY.

Benjamin A. Schenkel University at Albany, State University of New York, and Robert E. Hart, The Florida State University 38 th.

Dynamics and predictability of the rapid intensification of Hurricane Edouard (2014) Erin Munsell Summer 2015 Group Meeting August 17 th, 2015.

Multi-Scale Analysis of the Kinematic and Thermodynamic Structure of TS Humberto Using Dropsonde and Satellite Data Jeffrey B. Halverson, UMBC Alex Martin,

Satellite + Aircraft Tropical Cyclone Surface Wind Analysis Joint Hurricane Testbed.

Ventilation of Tropical Cyclones Brian Tang ATM 741 3/21/16.

2003 Atlantic Hurricane Season Summary By Gerald Bell, Muthuvel Chelliah Climate Prediction Center NOAA/ NWS And NOAA Atlantic Hurricane forecast team.

INNER CORE STRUCTURE AND INTENSITY CHANGE IN HURRICANE ISABEL (2003) Shuyi S. Chen and Peter J. Kozich RSMAS/University of Miami J. Gamache, P. Dodge,

JP1.18 Physical processes associated with surface wind field uncertainty in Hurricanes Katrina and Rita (2005): Use of present and future observational.

Formation of a hurricane in a sheared environment John Molinari, David Vollaro, and Kristen L. Corbosiero Note: these figures should be examined along.

Shuyi S. Chen, Robert A. Houze Bradley Smull, David Nolan, Wen-Chau Lee Frank Marks, and Robert Rogers Observational and Modeling Study of Hurricane Rainbands.

The Centre for Australian Weather and Climate Research A partnership between CSIRO and the Bureau of Meteorology The Tropical Cyclone Boundary Layer 2:

The Active 2008 Atlantic Hurricane Season Links to Known Climate Factors Gerry Bell NOAA Lead Seasonal Hurricane Forecaster Climate Prediction Center.

Diagnosing the Intensity of Super Typhoon Haiyan

Andrea Schumacher1, M. DeMaria2, and R. DeMaria1

Evolution of Hurricane Isabel’s (2003) Vortex Structure and Intensity

Accounting for Variations in TC Size

Derek Ortt1 and Shuyi S. Chen, RSMAS/University of Miami

Yumin Moon & David S. Nolan (2014)

Wallace A. Hogsett and Stacy R. Stewart

The Genesis of Hurricane Guillermo: TEXMEX Analyses and a Modeling Study BISTER AND EMANUEL.

Spiral Rainbands in a Numerical Simulation of Hurricane Bill (2009)

Tropical Cyclone Structure

The Inner-Core Temperature Structure of Hurricane Edouard (2014): Observations and Ensemble Variability Erin B. Munsell, Fuqing Zhang, Scott A. Braun,

Bell, M. M. , M. T. Montgomery, and W. -C

台风的暖心结构与强度变化(1) 储可宽组会.

Comparison of secondary eyewall and principal rainband in Hurricane Rita (2005) Not a modeling study Several theories out there for secondary eyewall formation.

Hurricanes This chapter discusses:

Tong Zhu and Da-Lin Zhang

A Multiscale Numerical Study of Hurricane Andrew (1992)

GEORGE H. BRYAN and RICHARD ROTUNNO 2009, J. Atmos. Sci., 66,

Xu, H., and X. Li, 2017 J. Geophys. Res. Atmos., 122, 6004–6024

Presentation transcript:

Thermodynamic Structure of Tropical Cyclones From Aircraft Reconnaissance Kay Shelton University at Albany/SUNY, Albany, New York

US Air Force reconnaissance flights. –Archive maintained by John Knaff (CIRA) , 77 storms  619 flights. Equivalent potential temperature  e. –Bolton (1980). Case-study: Bret, –Comparison of  e and windspeed through storm evolution from tropical depression through to category 4 hurricane. Composite of all storms. –Data every 30s, averaged into 20km radial bins –(>5 points per bin to be included) –Categorised average  e profiles by level and intensity. DATA AND METHODOLOGY

Instrument wetting errors (IWE). –Eastin et al. (2002).LIMITATION Adapted from Eastin et al. 2002b IWE minimised away from eyewall. In eyewall, maximum mean error < 3K. Removal of IWE acts to move maximum radial gradient towards outer edge of eyewall. Errors may be larger for individual cases.

Hurricane Bret, –Organised to TD at 18Z on 18 th August, in Bay of Campeche. –Bret strengthened to category 4, then decreased to category 3 prior to landfall on Padre Island, TX at 00Z on 23 rd August. –Scatter plots of  e and windspeed in six flights will be shown. CASE STUDY

<500m TD-TS TS <500m ee Windspeed

TS H1-H2 ~850hPa 37.5km ee Windspeed

H4 H4-H3 ~700hPa 17.8km 32.5km ee Windspeed

COMPOSITE Flight level must increase as storms intensify. Weaker systems have fewer flights above PBL, stronger systems have fewer flights below 700hPa. Comparison between levels at a given intensity is limited to TS and H1.

COMPOSITE INWARD RADIAL GRADIENT OF  e -  e /  r ( K/100km) <500m ~850hPa ~700hPa

 e DIFFERENCE BETWEEN 2 LEVELS TS:  e (BL) –  e (850hPa)H1:  e (850hPa) –  e (700hPa)  e (K)   Arrows indicate relevant tropical environment  e /  p (Jordan, 1958)

SUMMARY RADIAL TD: |  e /  r| ~ 0 at all radii TS:  e increases first in the core (r<90km) H1-H4: |  e /  r| increases with intensity, within r=100km VERTICAL TS and H1: In lower troposphere convective instability increases outward. –Both profiles are close to convective neutrality near storm centre and convective instability increases outwards to their respective tropical environmental values.