Аннотация:
The transition to dynamical chaos and the related lateral (cross-flow) transport of a passive
scalar in the reverse annular jet flow generating two chains of wave-vortex structures are studied.
The quasi-geostrophic equations for the barotropic (quasi-two-dimensional) flow written in
polar coordinates with allowance for the beta-effect and external friction are solved numerically
using a pseudospectral method. The critical parameters of the equilibrium flow with a complex
“two-hump” azimuth velocity profile facilitating a faster transition to the complex dynamics are
determined. Two regular multiharmonic regimes of wave generation are revealed with increasing
flow supercriticality before the onset of Eulerian chaos. The occurrence of the complex flow
dynamics is confirmed by a direct calculation of the largest Lyapunov exponent. The evolution
of streamline images is analyzed by making video, thereby chains with single and composite
structures are distinguished. The wavenumber-frequency spectra confirming the possibility of
chaotic transport of the passive scalar are drawn for the basic regimes of wave generation. The
power law exponents for the azimuth particle displacement and their variance, which proved
the occurrence of the anomalous azimuth transport of the passive scalar, are determined. Lagrangian
chaos is studied by computing the finite-time Lyapunov exponent and its distribution
function. The internal chain (with respect to the annulus center) is found to be totally subject
to Lagrangian chaos, while only the external chain boundary is chaotic. It is revealed that the
cross-flow transport occurs only in the regime of Eulerian dynamical chaos, since there exists a
barrier to it in the multiharmonic regimes. The images of fluid particles confirming the presence
of lateral transport are obtained and their quantitative characteristics are determined.
Ключевые слова:barotropic jet flow, chains of wave structures, Eulerian and Lagrangian chaos,
cross-flow chaotic transport.