25 June 200716th Conference on Atmospheric and Oceanic Fluid Dynamics Potential vorticity dynamics of a tropopause polar vortex Steven M. Cavallo and Gregory

25 June 2007 16th Conference on Atmospheric and Oceanic Fluid Dynamics

Potential vorticity dynamics of a tropopause polar vortex

Steven M. Cavallo

and Gregory J. Hakim

University of Washington

Department of Atmospheric Sciences


Outline

• Tropopause polar vortices (TPVs)

• Ertel Potential Vorticity (EPV)

• Mechanisms for vortex intensity changes

• November 2005 TPV

Overview and observations

Potential vorticity analysis

PV budget


What are tropopause polar vortices (TPVs)?

• Vortices that occur north and away from jet stream

• Based on tropopause

• Cold core

Vortices defined by closed contours of a materially conserved field such as PV

Changes in strength equivalent to changes in fluid properties within closed contours

Disturbances wave-like along jet stream


Why do we care about TPVs?

• Formation and intensity changes are not well understood

• Are often long-lived

Can have lifetimes > 1 month

• Trigger surface cyclones, such as in the image above

Eventually drift into midlatitudes and jet stream, impacting the weather


Ertel Potential Vorticity (EPV)


What EPV changes can we expect with a cloud?

Latent heating Heating rate



Latent heating EPV changes



Radiation Heating rate



Latent heating EPV changes



Radiation + Latent heating

Net EPV changes (radiation > latent heating)



Radiation + Latent heating

Net EPV changes (radiation < latent heating)


November 2005 TPV: Observations

GFS analysis tropopause pressure Coral Harbour, NT sounding

21 November 2005 at 00 UTC


November 2005 TPV: Observations

GFS analysis tropopause pressure Coral Harbour, NT sounding

22 November 2005 at 00 UTC


November 2005 TPV

WRF (V. 2.1.2) simulations:

• X = 30 km, Nz = 31

• 5-class microphysics, RRTM longwave radiation

• GFS initial conditions, boundaries updated every 3 hours

GFS Tropopause Analysis


November 2005 TPV

WRF (V. 2.1.2) simulations:

• X = 30 km, Nz = 31

• 5-class microphysics, RRTM longwave radiation

• GFS initial conditions, boundaries updated every 3 hours

GFS Tropopause Analysis


November 2005 TPV: Strengthening

PV Budget: Time mean vertical profiles for Siberia segment

All EPV components Diabatic components



Time-height: Diabatic components Diabatic components

PV Budget



Time-height: Radiation and cloud Diabatic components

PV Budget



Time-height: Latent heat + Radiation Diabatic components

PV Budget


November 2005 TPV: Weakening

PV Budget: Time mean vertical profiles for Hudson Bay segment

All EPV components Diabatic components


Summary

•TPV strengthening from cloud-top radiational cooling in November 2005 TPV

•TPV weakening processes not clear, but strengthening no longer appears to occur when latent heating effects dominate the radiational effects.

• Is radiation always the key driver? What dynamics control weakening?

Work is underway involving idealized experiments to isolate the dynamics responsible for TPV intensity changes.



What can we expect from a cloud?

Documents

25 June 200716th Conference on Atmospheric and Oceanic Fluid Dynamics Potential vorticity dynamics of a tropopause polar vortex Steven M. Cavallo and Gregory