Barotropic Vortex Adjustment to Asymmetric Forcing with Application to Tropical Cyclone Motion
Abstract
A nondivergent, barotropic analytical model to predict steady tropical cyclone (TC) propagation relative to the large-scale environment is developed in terms of a 'self-advection' process in which the TC is advected by an azimuthal wavenumber one gyre flow that results from TC-environment interaction. The model is comprehensive in that it includes the first-order effects of all of the dynamic influences that are presently understood to be important to barotropic propagation: gradients of planetary and environmental vorticity, changes in TC wind structure, and environmental windshear. An unforced version of the model is used to show that angular windshear in the symmetric TC circulation acts to damp perturbations from axisymmetry. Thus, steady propagation of TC-like barotropic vortices is a manifestation of a stable response to asymmetric forcing. To predict both the asymmetric gyre flow and the propagation it induces, the forced Barotropic Self-Advection Model (BSAM) is closed by seeking a particular pattern in the vorticity tendencies of the TC- environmental interaction flow. For realistic combinations of environmental vorticity gradients and linear windshear, the BSAM predicts propagation speeds and directions that are consistent with TC propagation characteristics observed in composite data. Vortex stability/propagation, Dissertations.
Document Details
- Document Type
- Technical Report
- Publication Date
- Sep 01, 1989
- Accession Number
- ADA219883
Entities
People
- Lester E. Carr Iii
Organizations
- Naval Postgraduate School