Repulsive chemotaxis and predator evasion in predator prey models with diffusion and prey taxis

Abstract

The role of predator evasion mediated by chemical signaling is studied in a diffusive prey-predator model when prey-taxis is taken into account (model A) or not (model B) with taxis strength coefficients and respectively. In the kinetic part of the models it is assumed that the rate of prey consumption includes functional responses of Holling, Bedington-DeAngelis or Crowley-Martin. Existence of global-in-time classical solutions to model A is proved in space dimension n=1 while to model B for any n≥ 1. The Crowley-Martin response combined with bounded rate of signal production precludes blow-up of solution in model A for n≤ 3. Local and global stability of a constant coexistence steady state which is stable for ODE and purely diffusive model are studied along with mechanism of Hopf bifurcation for Model B when exceeds some critical value. In model A it is shown that prey taxis may destabilize the coexistence steady state provided and are big enough. Numerical simulation depicts emergence of complex space-time patterns for both models and indicate existence of solutions to model A which blow-up in finite time for n=2