Presentation is loading. Please wait.

Presentation is loading. Please wait.

Subtropical Cyclones Diabatic Energy Sources Baroclinic Energy Sources Adapted from Fig. 9 in Beven (2012) 30 th Conference on Hurricanes and Tropical.

Published byMarjorie Lynch Modified over 8 years ago

Similar presentations

Presentation on theme: "Subtropical Cyclones Diabatic Energy Sources Baroclinic Energy Sources Adapted from Fig. 9 in Beven (2012) 30 th Conference on Hurricanes and Tropical."— Presentation transcript:

1 Subtropical Cyclones Diabatic Energy Sources Baroclinic Energy Sources Adapted from Fig. 9 in Beven (2012) 30 th Conference on Hurricanes and Tropical Meteorology TCs Subtropical cyclones Frontal cyclones

2 Davis (2010) methodology: –Based on Ertel potential vorticity (PV) –Formulated in terms of two PV metrics that quantify the relative contributions of baroclinic processes and condensation heating to the evolution of individual cyclones Davis (2010) methodology is similar to Hart (2003) cyclone phase space diagrams Adapted Davis (2010) Methodology

3 Lower-tropospheric baroclinic processes: (near-surface potential temperature anomaly) absolute vorticity 425 hPa Potential temperature anomaly Length of 6° box centered on cyclone

4 Adapted Davis (2010) Methodology PV1/PV2 : measure of the contribution of lower-tropospheric baroclinic processes relative to the contribution of condensation heating Lower-tropospheric baroclinic processes: (near-surface potential temperature anomaly) Midtropospheric latent heat release: (interior PV anomaly) 425 hPa Ertel PV anomaly Potential temperature anomaly Length of 6° box centered on cyclone absolute vorticity

5 Adapted Davis (2010) Methodology 200 hPa 925 hPa

6 Lower-tropospheric baroclinic processes (PV1) 200 hPa 925 hPa Adapted Davis (2010) Methodology Lower-tropospheric baroclinic processes: (near-surface potential temperature anomaly)

7 Lower-tropospheric baroclinic processes (PV1) 200 hPa 925 hPa Adapted Davis (2010) Methodology Lower-tropospheric baroclinic processes: (near-surface potential temperature anomaly) Midtropospheric latent heat release: (interior PV anomaly)

8 500 hPa Lower-tropospheric baroclinic processes (PV1) 200 hPa 925 hPa Adapted Davis (2010) Methodology Lower-tropospheric baroclinic processes: (near-surface potential temperature anomaly) Midtropospheric latent heat release: (interior PV anomaly) PV1/PV2 : measure of the contribution of lower-tropospheric baroclinic processes relative to the contribution of condensation heating

9 Adapted Davis (2010) Methodology Additional metric introduced to diagnose upper-tropospheric dynamical processes Upper-tropospheric dynamical processes: (upper-tropospheric PV anomaly) Ertel PV anomaly 300 hPa Length of 6° box centered on cyclone

10 500 hPa Lower-tropospheric baroclinic processes (PV1) 200 hPa 925 hPa Adapted Davis (2010) Methodology Lower-tropospheric baroclinic processes: (near-surface potential temperature anomaly) Midtropospheric latent heat release: (interior PV anomaly) PV1/PV2 : measure of the contribution of lower-tropospheric baroclinic processes relative to the contribution of condensation heating

11 500 hPa Lower-tropospheric baroclinic processes (PV1) 200 hPa 925 hPa Adapted Davis (2010) Methodology Upper- tropospheric dynamical processes (PV3) Lower-tropospheric baroclinic processes: (near-surface potential temperature anomaly) Midtropospheric latent heat release: (interior PV anomaly) Upper-tropospheric dynamical processes: (upper-tropospheric PV anomaly) PV1/PV2 : measure of the contribution of lower-tropospheric baroclinic processes relative to the contribution of condensation heating

12 500 hPa Lower-tropospheric baroclinic processes (PV1) 200 hPa 925 hPa Adapted Davis (2010) Methodology Upper- tropospheric dynamical processes (PV3) PV1/PV2 : measure of the contribution of lower-tropospheric baroclinic processes relative to the contribution of condensation heating Calculated from the 0.5° Climate Forecast System Reanalysis V2 dataset

13 Hurricane Sandy: 6° × 6° box, NHC Best Track Peaks in PV3 PV1/PV2 22 October23 October24 October25 October26 October27 October28 October29 October30 October31 October PVU

14 Hurricane Sandy: 10° × 10° box, NHC Best Track Peaks in PV3 PV1/PV2 PVU 22 October23 October24 October25 October26 October27 October28 October29 October30 October31 October

15 Hurricane Sandy: 12° × 12° box, NHC Best Track Peaks in PV3 PV1/PV2 PVU 22 October23 October24 October25 October26 October27 October28 October29 October30 October31 October

16 Hurricane Sandy: 14° × 14° box, NHC Best Track PVU PV1/PV2 Peaks in PV3 22 October23 October24 October25 October26 October27 October28 October29 October30 October31 October

17 Hurricane Sandy: 16° × 16° box, NHC Best Track PVU PV1/PV2 Peaks in PV3 22 October23 October24 October25 October26 October27 October28 October29 October30 October31 October

18 Hurricane Sandy: 18° × 18° box, NHC Best Track PVU PV1/PV2 Peaks in PV3 22 October23 October24 October25 October26 October27 October28 October29 October30 October31 October

19 Hurricane Sandy: 20° × 20° box, NHC Best Track PVU PV1/PV2 Peaks in PV3 22 October23 October24 October25 October26 October27 October28 October29 October30 October31 October

20 500 hPa Lower-tropospheric baroclinic processes (PV1) 200 hPa 925 hPa Adapted Davis (2010) Methodology Upper- tropospheric dynamical processes (PV3) Lower-tropospheric baroclinic processes: (near-surface potential temperature anomaly) Midtropospheric latent heat release: (interior PV anomaly) Upper-tropospheric dynamical processes: (upper-tropospheric PV anomaly) PV1/PV2 : measure of the contribution of lower-tropospheric baroclinic processes relative to the contribution of condensation heating

21 300 hPa Lower-tropospheric baroclinic processes (PV1) 200 hPa 925 hPa Adapted Davis (2010) Methodology Upper- tropospheric dynamical processes (PV3) Lower-tropospheric baroclinic processes: (near-surface potential temperature anomaly) Midtropospheric latent heat release: (interior PV anomaly) Upper-tropospheric dynamical processes: (upper-tropospheric PV anomaly) PV1/PV2 : measure of the contribution of lower-tropospheric baroclinic processes relative to the contribution of condensation heating

22 Hurricane Sandy: 6° × 6° box, 500 hPa, NHC Best Track Peaks in PV3 22 October23 October24 October25 October26 October27 October28 October29 October30 October31 October PVU PV1/PV2

23 Peaks in PV3 22 October23 October24 October25 October26 October27 October28 October29 October30 October31 October Hurricane Sandy: 6° × 6° box, 300 hPa, NHC Best Track PVU PV1/PV2

24 300 hPa Lower-tropospheric baroclinic processes (PV1) 200 hPa 925 hPa Adapted Davis (2010) Methodology Upper- tropospheric dynamical processes (PV3) Lower-tropospheric baroclinic processes: (near-surface potential temperature anomaly) Midtropospheric latent heat release: (interior PV anomaly) Upper-tropospheric dynamical processes: (upper-tropospheric PV anomaly) PV1/PV2 : measure of the contribution of lower-tropospheric baroclinic processes relative to the contribution of condensation heating

25 500 hPa Lower-tropospheric baroclinic processes (PV1) 200 hPa 925 hPa Adapted Davis (2010) Methodology Upper- tropospheric dynamical processes (PV3) PV1/PV2 : measure of the contribution of lower-tropospheric baroclinic processes relative to the contribution of condensation heating Calculated from the 0.5° Climate Forecast System Reanalysis V2 dataset

Download ppt "Subtropical Cyclones Diabatic Energy Sources Baroclinic Energy Sources Adapted from Fig. 9 in Beven (2012) 30 th Conference on Hurricanes and Tropical."

Similar presentations

The Influence of Extratropical Transition on Poleward Rossby Wave Breaking Lisa-Ann Quandt, J. H. Keller 1, S. C. Jones 1, A. Schneidereit 2, D. H. Peters.

The Influence of Extratropical Transition on Poleward Rossby Wave Breaking Lisa-Ann Quandt, J. H. Keller 1, S. C. Jones 1, A. Schneidereit 2, D. H. Peters.
The Structural Evolution of African Easterly Waves Matthew A. Janiga and Chris Thorncroft DEPARTMENT OF ATMOSPHERIC AND ENVIRONMENTAL SCIENCES University.

The Structural Evolution of African Easterly Waves Matthew A. Janiga and Chris Thorncroft DEPARTMENT OF ATMOSPHERIC AND ENVIRONMENTAL SCIENCES University.
Hurricanes and Climate Change: What do the Observations Show? Hurricanes and Climate Change: What do the Observations Show? 25 April 2012 Chris Landsea,

Hurricanes and Climate Change: What do the Observations Show? Hurricanes and Climate Change: What do the Observations Show? 25 April 2012 Chris Landsea,
HURRICANE GORDON and the NWP models near the Iberian Peninsula.

HURRICANE GORDON and the NWP models near the Iberian Peninsula.
Tropical Transition Climatology R. McTaggart-Cowan, L. F. Bosart, C. A. Davis and G. Deane.

Tropical Transition Climatology R. McTaggart-Cowan, L. F. Bosart, C. A. Davis and G. Deane.
Chap. 5 Conceptual models of synoptic Tropical disturbances in summer Definition of tropical disturbances : A discrete tropical weather system of apparently.

Chap. 5 Conceptual models of synoptic Tropical disturbances in summer Definition of tropical disturbances : A discrete tropical weather system of apparently.
Niels Woetmann Nielsen Danish Meteorological Institute

Niels Woetmann Nielsen Danish Meteorological Institute
Benjamin A. Schenkel and Robert E. AMS Tropical Conference 2012 Department of Earth, Ocean, and Atmospheric Science.

Benjamin A. Schenkel and Robert E. AMS Tropical Conference 2012 Department of Earth, Ocean, and Atmospheric Science.
A Multiscale Analysis of the Inland Reintensification of Tropical Cyclone Danny (1997) within an Equatorward Jet-Entrance Region Matthew S. Potter, Lance.

A Multiscale Analysis of the Inland Reintensification of Tropical Cyclone Danny (1997) within an Equatorward Jet-Entrance Region Matthew S. Potter, Lance.
Synoptic Structure of AEWs Matthew Janiga. Tracking Methodology Apply a 2-day low-pass filter with a 100 day window to circulation calculated within a.

Synoptic Structure of AEWs Matthew Janiga. Tracking Methodology Apply a 2-day low-pass filter with a 100 day window to circulation calculated within a.
EASTERLY WAVE STRUCTURAL EVOLUTION OVER WEST AFRICA AND THE EAST ATLANTIC Matthew A. Janiga Department of Atmospheric and Environmental Sciences, University.

EASTERLY WAVE STRUCTURAL EVOLUTION OVER WEST AFRICA AND THE EAST ATLANTIC Matthew A. Janiga Department of Atmospheric and Environmental Sciences, University.
An Unusual Pathway to Oceanic Cyclogenesis Linking “Perfect Storms” in the North Atlantic Ocean Jason M. Cordeira and Lance F. Bosart Department of Earth.

An Unusual Pathway to Oceanic Cyclogenesis Linking “Perfect Storms” in the North Atlantic Ocean Jason M. Cordeira and Lance F. Bosart Department of Earth.
PV Budgeting on tropopause polar vortices Steven Cavallo University of Washington Group Meeting September 27, 2005.

PV Budgeting on tropopause polar vortices Steven Cavallo University of Washington Group Meeting September 27, 2005.
The Contribution of Eastern North Pacific Tropical Cyclones to the Warm Season Rainfall Climatology of the Southwest US Kristen L. Corbosiero (UCLA) Michael.

The Contribution of Eastern North Pacific Tropical Cyclones to the Warm Season Rainfall Climatology of the Southwest US Kristen L. Corbosiero (UCLA) Michael.
Potential Vorticity (PV) as a Tool in Forecasting

Potential Vorticity (PV) as a Tool in Forecasting
Hurricane Juan (2003): A Diagnostic and Compositing Study Ron McTaggart-Cowan 1, Eyad Atallah 2, John Gyakum 2, and Lance Bosart 1 1 University of Albany,

Hurricane Juan (2003): A Diagnostic and Compositing Study Ron McTaggart-Cowan 1, Eyad Atallah 2, John Gyakum 2, and Lance Bosart 1 1 University of Albany,
The Extratropical Transitions of Danielle and Earl (1998) Ron McTaggart-Cowan J.R. Gyakum, M.K. Yau.

The Extratropical Transitions of Danielle and Earl (1998) Ron McTaggart-Cowan J.R. Gyakum, M.K. Yau.
Upper-Level Precursors Associated with Subtropical Cyclone Formation in the North Atlantic Alicia M. Bentley, Daniel Keyser, and Lance F. Bosart University.

Upper-Level Precursors Associated with Subtropical Cyclone Formation in the North Atlantic Alicia M. Bentley, Daniel Keyser, and Lance F. Bosart University.
Genesis Potential Index and ENSO Suzana J. Camargo.

Genesis Potential Index and ENSO Suzana J. Camargo.
1 26 April 2013 Future WorkResultsMethodologyMotivation Chip HelmsComposite Analyses of Tropical Convective Systems Composite Analyses of Tropical Convective.

1 26 April 2013 Future WorkResultsMethodologyMotivation Chip HelmsComposite Analyses of Tropical Convective Systems Composite Analyses of Tropical Convective.

Similar presentations

Ads by Google