We study the propagation profile of the solution u(x,t) to the nonlinear
diffusion problem utββΞu=f(u)(xβRN,t>0),
u(x,0)=u0β(x)(xβRN), where f(u) is of multistable type:
f(0)=f(p)=0, fβ²(0)<0, fβ²(p)<0, where p is a positive constant, and f
may have finitely many nondegenerate zeros in the interval (0,p). The class
of initial functions u0β includes in particular those which are nonnegative
and decay to 0 at infinity. We show that, if u(β ,t) converges to p as
tββ in Llocββ(RN), then the long-time dynamical
behavior of u 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 Ξ½βSNβ1, u(xβ Ξ½,t) converges to a pair of one dimensional propagating terraces, one moving in
the direction of xβ Ξ½>0, and the other is its reflection moving in the
opposite direction xβ Ξ½<0.
Our approach relies on the introduction of the notion "radial terrace
solution", by which we mean a special solution V(β£xβ£,t) of VtββΞV=f(V) such that, as tββ, 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) can be well
approximated by a suitablly shifted radial terrace solution V(β£xβ£,t). These
will enable us to obtain better convergence result for u(x,t).
We stress that 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