Superdiffusive limits for deterministic fast-slow dynamical systems (1907.04825v2)

Abstract: We consider deterministic fast-slow dynamical systems on $\mathbb{R}^m\times Y$ of the form [ \begin{cases} x_{k+1}^{(n)} = x_k^{(n)} + n^{-1} a(x_k^{(n)}) + n^{-1/\alpha} b(x_k^{(n)}) v(y_k)\;,\quad y_{k+1} = f(y_k)\;, \end{cases} ] where $\alpha\in(1,2)$. Under certain assumptions we prove convergence of the $m$-dimensional process $X_n(t)= x_{\lfloor nt \rfloor}^{(n)}$ to the solution of the stochastic differential equation [ \mathop{}!\mathrm{d} X = a(X)\mathop{}!\mathrm{d} t + b(X) \diamond \mathop{}!\mathrm{d} L_\alpha \; , ] where $L_\alpha$ is an $\alpha$-stable L\'evy process and $\diamond$ indicates that the stochastic integral is in the Marcus sense. In addition, we show that our assumptions are satisfied for intermittent maps $f$ of Pomeau-Manneville type.