Asymptotic limit of the principal eigenvalue of asymmetric nonlocal diffusion operators and propagation dynamics
Abstract
For fixed c∈ R, l>0 and a general non-symmetric kernel function J(x) satisfying a standard assumption, we consider the nonlocal diffusion operator align* LJ, c(-l,l)[φ](x):=∫-llJ(x-y)φ(y)\,dy+cφ'(x), align* and prove that its principal eigenvalue λp(LJ, c(-l,l)) has the following asymptotic limit: equation*l-to-infty-c l ∞λp( LJ, c(-l,l))=∈f∈R[∫RJ(x)e- x\,dx+c]. equation* We then demonstrate how this result can be applied to determine the propagation dynamics of the associated Cauchy problem equation* cau \ arrayll ut = d [∫R J(x-y) u(t,y) \, dy - u(t,x)] + f(u), & t > 0, \; x ∈ R, u(0, x) = u0(x), & x ∈ R, array . equation* with a KPP nonlinear term f(u). This provides a new approach to understand the propagation dynamics of KPP type models, very different from those based on traveling wave solutions or on the dynamical systems method of Weinberger (1982).
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