Maximizing the spreading speed of KPP fronts in two-dimensional stratified media

Abstract

We consider the equation ut=uxx+uyy+b(x)f(u)+g(u), (x,y)∈ R2 with monostable nonliearity, where b(x) is a nonnegative measure on R that is periodic in x. In the case where b(x) is a smooth periodic function, there exists a pulsating travelling wave that propagates in the direction (θ,θ) -- with average speed c if and only if c≥ c*(θ,b), where c*(θ,b) is a certain positive number depending on b. Moreover, the quantity w(θ;b)=|θ-φ|<π2c*(φ;b)/(θ-φ) is called the spreading speed. This theory can be extended by showing the existence of the minimal speed c*(θ,b) for any nonnegative measure b with period L. We then study the question of maximizing c*(θ,b) under the constraint ∫[0,L)b(x)dx=α L, where α is an arbitrarily given positive constant. We prove that the maximum is attained by periodically arrayed Dirac's delta functions h(x)=α LΣk∈ Zδ(x+kL) for any direction θ. Based on these results, for the case that b=h we also show the monotonicity of the spreading speedsin θ and study the asymptotic shape of spreading fronts for large L and small L . Finally, we show that for general 2-dimensional periodic equation ut=uxx+uyy+b(x,y)f(u)+g(u), (x,y)∈ R2, the similar conclusions do not hold.