26th Conference on Hurricanes and Tropical Meteorology

P1.67

Damping and pumping of a vortex Rossby wave in a monotonic cyclone: critical layer stirring versus inertia-buoyancy wave emission

David A. Schecter, Colorado State University, Fort Collins, CO; and M. T. Montgomery

This work further examines the rate at which potential vorticity in the core of a monotonic cyclone becomes vertically aligned and horizontally axisymmetric. We consider the case in which symmetrization occurs by the damping of a vortex Rossby (VR) wave. The damping of the VR wave is caused by its stirring of potential vorticity at a critical radius r*, outside the core of the cyclone. The decay rate generally increases with the radial gradient of potential vorticity at r*. Previous theories for the decay rate were based on "balance models'' of the vortex dynamics. Such models filter out inertia-buoyancy (IB) oscillations, i.e. gravity waves. However, if the Rossby number is greater than unity, the core VR wave can emit a frequency-matched outward propagating IB wave into the environment. To accurately account for this radiation, we here develop a theory for the decay rate that is based on the primitive equations. The decay rate is obtained analytically by considering conservation of wave activity (angular pseudomomentum). The analytical expression makes clear that the core VR wave experiences negative feedback from potential vorticity stirring at r*, and positive feedback from IB wave radiation. The negative feedback will dominate (and the vortex will symmetrize) if the radial gradient of potential vorticity at r* exceeds a small threshold. The possible relevance of this theory toward understanding the evolution of a tropical cyclone is discussed.

extended abstract  Extended Abstract (92K)

Poster Session 1, Posters
Wednesday, 5 May 2004, 1:30 PM-1:30 PM, Richelieu Room

Previous paper  Next paper

Browse or search entire meeting

AMS Home Page