Your search keyword '"José D. Szezech"' showing total 3 results

1. Dynamical characterization of transport barriers in nontwist Hamiltonian systems

Author

Michele Mugnaine, M. S. Santos, Antonio M. Batista, R. L. Viana, A. C. Mathias, and José D. Szezech

Subjects

Physics, Chaotic, Boundary (topology), Flux, 01 natural sciences, 010305 fluids & plasmas, Hamiltonian system, Turnstile, Uncertainty exponent, 0103 physical sciences, Statistical physics, Homoclinic orbit, Twist, 010306 general physics

Abstract

The turnstile provides us a useful tool to describe the flux in twist Hamiltonian systems. Thus, its determination allows us to find the areas where the trajectories flux through barriers. We show that the mechanism of the turnstile can increase the flux in nontwist Hamiltonian systems. A model which captures the essence of these systems is the standard nontwist map, introduced by del Castillo-Negrete and Morrison. For selected parameters of this map, we show that chaotic trajectories entering in resonances zones can be explained by turnstiles formed by a set of homoclinic points. We argue that for nontwist systems, if the heteroclinic points are sufficiently close, they can connect twin-islands chains. This provides us a scenario where the trajectories can cross the resonance zones and increase the flux. For these cases the escape basin boundaries are nontrivial, which demands the use of an appropriate characterization. We applied the uncertainty exponent and the entropies of the escape basin boundary in order to quantify the degree of unpredictability of the asymptotic trajectories.

Published

2018

2. Mechanism for stickiness suppression during extreme events in Hamiltonian systems

Author

P. P. Galuzio, Sergio Roberto Lopes, T. L. Prado, José D. Szezech, Ricardo L. Viana, and Taline Suellen Kruger

Subjects

Nonlinear Sciences::Chaotic Dynamics, Physics, Classical mechanics, Phase space, Trajectory, Extreme events, Non-equilibrium thermodynamics, Geometry, Approx, Fixed point, Hamiltonian system

Abstract

In this paper we study how hyperbolic and nonhyperbolic regions in the neighborhood of a resonant island perform an important role allowing or forbidding stickiness phenomenon around islands in conservative systems. The vicinity of the island is composed of nonhyperbolic areas that almost prevent the trajectory to visit the island edge. For some specific parameters tiny channels are embedded in the nonhyperbolic area that are associated to hyperbolic fixed points localized in the neighborhood of the islands. Such channels allow the trajectory to be injected in the inner portion of the vicinity. When the trajectory crosses the barrier imposed by the nonhyperbolic regions, it spends a long time abandoning the vicinity of the island, since the barrier also prevents the trajectory from escaping from the neighborhood of the island. In this scenario the nonhyperbolic structures are responsible for the stickiness phenomena and, more than that, the strength of the sticky effect. We show that those properties of the phase space allow us to manipulate the existence of extreme events (and the transport associated to it) responsible for the nonequilibrium fluctuation of the system. In fact we demonstrate that by monitoring very small portions of the phase space (namely, $\ensuremath{\approx}1\ifmmode\times\else\texttimes\fi{}{10}^{\ensuremath{-}5}%$ of it) it is possible to generate a completely diffusive system eliminating long-time recurrences that result from the stickiness phenomenon.

Published

2015

3. Onset of spatiotemporal chaos in a nonlinear system

Author

José D. Szezech, Ricardo L. Viana, and Sergio Roberto Lopes

Subjects

Nonlinear Sciences::Chaotic Dynamics, Control of chaos, Nonlinear system, Polynomial chaos, Classical mechanics, law, Intermittency, Invariant manifold, Quantum chaos, Chaos theory, Mathematics, law.invention, Coupled map lattice

Abstract

We describe the onset of spatiotemporal chaos in a spatially extended nonlinear dynamical system as a result of the loss of transversal stability of an invariant manifold representing a spatially homogeneous and temporally chaotic state. The onset of spatiotemporal chaos is characterized by the switching between spatially homogeneous and nonhomogeneous states with statistical properties of on-off intermittency.

Published

2007