Large time behavior and transition from vanishing to spreading regimes for the generalized Burgers-Fisher-KPP equation

Abstract

The large time behavior of solutions to the following generalized Burgers-Fisher-KPP equation ∂tu=uxx+k(un)x+up-uq, (x,t)∈R×(0,∞), with n≥2, p>q≥1 and k∈R, is considered in this work. Denoting by H(x,t), respectively H(x,t) the solutions having as initial condition the Heaviside, respectively the ``anti-Heaviside" functions H0(x)=cases 0, & if x<0 1, & if x≥0. cases, H0(x)=1-H0(x), critical velocities c, respectively c=kn+2p-q, are identified such that H(x,t), respectively H(x,t) approach the unique traveling wave solution of the equation with these critical velocities as t∞. The critical velocity c is anomalous, that is, it cannot be made explicit by an algebraic expression. Assuming for simplicity k>0, a remarkable fact is that, while H(x,t)0 as t∞ uniformly on compact subsets of R, the Heaviside solution H might tend either to zero or to one as t∞, depending on the sign of the critical velocity c. This sign vary with respect to the exponents n, p, q and the coefficient k and, in fact, we prove that given p, q, n, there exists a critical coefficient k*(n,p,q) such that c>0 if k>k*(n,p,q) and c<0 if k<k*(n,p,q). The convergence to either zero or one reflects the sharp influence of the convection term, since in the absence of it (that is, k=0), H(x,t) would always tend to zero as t∞. The results include more general initial conditions than the Heaviside-type functions, and sharp estimates of the threshold coefficient k*(n,p,q) are also given.