212 research outputs found

    Radial terrace solutions and propagation profile of multistable reaction-diffusion equations over RN\mathbb R^N

    Full text link
    We study the propagation profile of the solution u(x,t)u(x,t) to the nonlinear diffusion problem utΔu=f(u)  (xRN,  t>0)u_t-\Delta u=f(u)\; (x\in \mathbb R^N,\;t>0), u(x,0)=u0(x)  (xRN)u(x,0)=u_0(x) \; (x\in\mathbb R^N), where f(u)f(u) is of multistable type: f(0)=f(p)=0f(0)=f(p)=0, f(0)<0f'(0)<0, f(p)<0f'(p)<0, where pp is a positive constant, and ff may have finitely many nondegenerate zeros in the interval (0,p)(0, p). The class of initial functions u0u_0 includes in particular those which are nonnegative and decay to 0 at infinity. We show that, if u(,t)u(\cdot, t) converges to pp as tt\to\infty in Lloc(RN)L^\infty_{loc}(\mathbb R^N), then the long-time dynamical behavior of uu is determined by the one dimensional propagating terraces introduced by Ducrot, Giletti and Matano [DGM]. For example, we will show that in such a case, in any given direction νSN1\nu\in\mathbb{S}^{N-1}, u(xν,t)u(x\cdot \nu, t) converges to a pair of one dimensional propagating terraces, one moving in the direction of xν>0x\cdot \nu>0, and the other is its reflection moving in the opposite direction xν<0x\cdot\nu<0. Our approach relies on the introduction of the notion "radial terrace solution", by which we mean a special solution V(x,t)V(|x|, t) of VtΔV=f(V)V_t-\Delta V=f(V) such that, as tt\to\infty, V(r,t)V(r,t) converges to the corresponding one dimensional propagating terrace of [DGM]. We show that such radial terrace solutions exist in our setting, and the general solution u(x,t)u(x,t) can be well approximated by a suitablly shifted radial terrace solution V(x,t)V(|x|, t). These will enable us to obtain better convergence result for u(x,t)u(x,t). We stress that u(x,t)u(x,t) is a high dimensional solution without any symmetry. Our results indicate that the one dimensional propagating terrace is a rather fundamental concept; it provides the basic structure and ingredients for the long-time profile of solutions in all space dimensions

    The singular limit of the Allen-Cahn equation and the FitzHugh-Nagumo system

    Get PDF
    We consider an Allen-Cahn type equation with a bistable nonlinearity associated to a double-well potential whose well-depths can be slightly unbalanced, and where the coefficient of the nonlinear reaction term is very small. Given rather general initial data, we perform a rigorous analysis of both the generation and the motion of interface. More precisely we show that the solution develops a steep transition layer within a small time, and we present an optimal estimate for its width. We then consider a class of reaction-diffusion systems which includes the FitzHugh-Nagumo system as a special case. Given rather general initial data, we show that the first component of the solution vector develops a steep transition layer and that all the results mentioned above remain true for this component

    Traveling Waves in Spatially Random Media (Mathematical Economics)

    Get PDF

    Front propagation through a perforated wall

    Full text link
    We consider a bistable reaction-diffusion equation ut=Δu+f(u)u_t=\Delta u +f(u) on RN\mathbb{R}^N in the presence of an obstacle KK, which is a wall of infinite span with many holes. More precisely, KK is a closed subset of RN\mathbb{R}^N with smooth boundary such that its projection onto the x1x_1-axis is bounded and that RNK\mathbb{R}^N \setminus K is connected. Our goal is to study what happens when a planar traveling front coming from x1=x_1 = -\infty meets the wall KK.We first show that there is clear dichotomy between "propagation" and "blocking". In other words, the traveling front either passes through the wall and propagates toward x1=+x_1=+\infty (propagation) or is trapped around the wall (blocking), and that there is no intermediate behavior. This dichotomy holds for any type of walls of finite thickness. Next we discuss sufficient conditions for blocking and propagation. For blocking, assuming either that KK is periodic in y:=(x2,,xN)y:=(x_2,\ldots, x_N) or that the holes are localized within a bounded area, we show that blocking occurs if the holes are sufficiently narrow. For propagation, three different types of sufficient conditions for propagation will be presented, namely "walls with large holes", "small-capacity walls", and "parallel-blade walls". We also discuss complete and incomplete invasions
    corecore