High multiplicity and chaos for an indefinite problem arising from genetic models

Abstract

We deal with the periodic boundary value problem associated with the parameter-dependent second-order nonlinear differential equation equation* u'' + cu' + ( λ a+(x) - μ a-(x) ) g(u) = 0, equation* where λ,μ>0 are parameters, c∈R, a(x) is a locally integrable P-periodic sign-changing weight function, and g[0,1] is a continuous function such that g(0)=g(1)=0, g(u)>0 for all u∈]0,1[, with superlinear growth at zero. A typical example for g(u), that is of interest in population genetics, is the logistic-type nonlinearity g(u)=u2(1-u). Using a topological degree approach, we provide high multiplicity results by exploiting the nodal behaviour of a(x). More precisely, when m is the number of intervals of positivity of a(x) in a P-periodicity interval, we prove the existence of 3m-1 non-constant positive P-periodic solutions, whenever the parameters λ and μ are positive and large enough. Such a result extends to the case of subharmonic solutions. Moreover, by an approximation argument, we show the existence of a countable family of globally defined solutions with a complex behaviour, coded by (possibly non-periodic) bi-infinite sequences of 3 symbols.