Homogenization of a multiscale model for water transport in vegetated soil

TL;DR

This paper develops a rigorous multiscale model for water movement in vegetated soil by deriving a macroscopic equation from microscopic Richards equations, addressing challenges of degeneracy and non-linearity.

Contribution

It introduces a novel multiscale homogenization approach for water transport in vegetated soil, incorporating root tissue effects and proving strong convergence.

Findings

Derived a macroscopic model using two-scale convergence and periodic unfolding.

Proved uniqueness and strong convergence of solutions despite equation degeneracy.

Addressed challenges of non-linearities and variable permeability in the model.

Abstract

In this paper we consider the multiscale modelling of water transport in vegetated soil. In the microscopic model we distinguish between subdomains of soil and plant tissue, and use the Richards equation to model the water transport through each. Water uptake is incorporated by means of a boundary condition on the surface between root tissue and soil. Assuming a simplified root system architecture, which gives a cylindrical microstructure to the domain, the two-scale convergence and periodic unfolding methods are applied to rigorously derive a macroscopic model for water transport in vegetated soil. The degeneracy of the Richards equation and the dependence of root tissue permeability on the small parameter introduce considerable challenges in deriving macroscopic equations, especially in proving strong convergence. The variable-doubling method is used to prove the uniqueness of solutions to the model, and also to show strong two-scale convergence in the non-linear terms of the equation for water transport through root tissue.