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Periodic modulation of time lag in nonlinear systems can dramatically boost chaotic diffusion. This enhancement, linked to Arnold tongues and laminar chaos, surprisingly reduces system dimensionality.

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Area of Science:

  • Nonlinear dynamics
  • Chaos theory
  • Statistical physics

Background:

  • Systems with delayed nonlinearity often exhibit complex behaviors, including chaotic diffusion.
  • Understanding how external factors influence these diffusive properties is crucial for various scientific fields.

Purpose of the Study:

  • To investigate the impact of periodic modulation of time lag on chaotic diffusion in nonlinear systems.
  • To establish a connection between Arnold tongue structures and diffusive properties.
  • To explore the relationship between diffusion enhancement and system dimensionality.

Main Methods:

  • Analysis of a typical class of systems with delayed nonlinearity.
  • Introduction of periodic modulation to the time lag parameter.
  • Examination of the circle map dynamics and conditions for laminar chaos.
  • Quantification of the diffusion constant and effective dimensionality.

Main Results:

  • Periodic modulation of time lag significantly enhances the diffusion constant, by orders of magnitude.
  • The largest enhancement occurs when the circle map exhibits mode locking and laminar chaos.
  • A direct link is established between Arnold tongue structures in parameter space and enhanced diffusion.
  • Increased diffusion is paradoxically accompanied by a substantial reduction in the system's effective dimensionality.

Conclusions:

  • Periodic modulation of time lag is a powerful tool to control and enhance chaotic diffusion.
  • Arnold tongue structures and laminar chaos conditions are key indicators for maximizing diffusion enhancement.
  • The counterintuitive reduction in dimensionality alongside diffusion enhancement opens new avenues for understanding complex systems.