Computational Mathematics and Modeling

, Volume 21, Issue 3, pp 308–319 | Cite as

Some new approaches to the solution of the diffusion chaos problem

  • N. A. Magnitskii, S. V. Sidorov
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Using the solution of the Kuramoto–Tsuzuki equation as an example, we present the results of numerical investigations of diffusion chaos in the neighborhood of the thermodynamic branch of the “reaction–diffusion” equation system. Chaos onset scenarios are considered both in the small-mode approximation and for the solution of the second boundary-value problem for the original equation. In the phase space of the Kuramoto–Tsuzuki equation chaos sets in through period doubling bifurcation cascades and through subharmonic bifurcation cascades of two-dimensional tori by both internal and external frequency. Chaos onset scenarios in the Kuramoto–Tsuzuki equation phase space and in the Fourier coefficient space are compared both for the small-mode approximation and for direct numerical solution of the second boundary-value problem. Inappropriateness of the three-dimensional small-mode approximations is proved.

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