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Weak chaos and metastability in a symplectic system of many long-range-coupled standard maps

arXiv:cond-mat/0602513 · doi:10.1140/epjb/e2006-00327-2

Abstract

We introduce, and numerically study, a system of $N$ symplectically and globally coupled standard maps localized in a $d=1$ lattice array. The global coupling is modulated through a factor $r^{-α}$, being $r$ the distance between maps. Thus, interactions are {\it long-range} (nonintegrable) when $0\leqα\leq1$, and {\it short-range} (integrable) when $α>1$. We verify that the largest Lyapunov exponent $λ_M$ scales as $λ_{M} \propto N^{-κ(α)}$, where $κ(α)$ is positive when interactions are long-range, yielding {\it weak chaos} in the thermodynamic limit $N\to\infty$ (hence $λ_M\to 0$). In the short-range case, $κ(α)$ appears to vanish, and the behaviour corresponds to {\it strong chaos}. We show that, for certain values of the control parameters of the system, long-lasting metastable states can be present. Their duration $t_c$ scales as $t_c \propto N^{β(α)}$, where $β(α)$ appears to be numerically consistent with the following behavior: $β>0$ for $0 \le α< 1$, and zero for $α\ge 1$. All these results exhibit major conjectures formulated within nonextensive statistical mechanics (NSM). Moreover, they exhibit strong similarity between the present discrete-time system, and the $α$-XY Hamiltonian ferromagnetic model, also studied in the frame of NSM.

8 pages, 5 figures