Bifurcation and pattern formation in diffusive Klausmeier-Gray-Scott model of water-plant interaction

A reaction-diffusion model describing water and plant interaction proposed by Klausmeier is studied. The existence of non-constant steady state solutions is shown through bifurcation methods, and the existence of large amplitude spatial patterned solutions is proved using associated shadow system. It is rigorously shown that non-homogeneous patterned vegetation states exist when the rainfall is at a lower level in which homogeneous vegetation state cannot survive. Even when the rainfall is very low, slow plant diffusion and fast water diffusion can support a vegetation state with vegetation concentrating on a small area. This provides an example of diffusion-induced persistence that non-constant steady states may exist in a reaction-diffusion system when there are no positive constant steady states. (C) 2020 Elsevier Inc. All rights reserved.

Automated summary

The reaction-diffusion model proposed by Klausmeier, describing water and plant interaction, shows the existence of non-constant steady state solutions and large amplitude spatial patterned solutions. It is proven that non-homogeneous patterned vegetation states exist when the rainfall is at a lower level.