Implicit and semi-implicit second-order time stepping methods for the Richards equation

TL;DR

This paper develops and compares second-order implicit and semi-implicit numerical methods for solving the Richards equation, focusing on efficiency, robustness, and convergence in various formulations and discretizations.

Contribution

It introduces second-order semi-implicit schemes using extrapolation and Taylor approximations, demonstrating improved performance over existing methods.

Findings

Semi-implicit schemes are effective alternatives to implicit methods.

Mixed formulations with standard finite elements outperform other discretizations.

Numerical tests confirm the robustness and efficiency of the proposed schemes.

Abstract

This study concerns numerical methods for efficiently solving the Richards equation where different weak formulations and computational techniques are analyzed. The spatial discretizations are based on standard or mixed finite element methods. Different implicit and semi-implicit temporal discretization techniques of second-order accuracy are studied. To obtain a linear system for the semi-implicit schemes, we propose second-order techniques using extrapolation formulas and/or semi-implicit Taylor approximations for the temporal discretization of nonlinear terms. A numerical convergence study and a series of numerical tests are performed to analyze efficiency and robustness of the different schemes. The developed scheme, based on the proposed temporal extrapolation techniques and the mixed formulation involving the saturation and pressure head and using the standard linear Lagrange element, performs better than other schemes based on the saturation and the flux and using the Raviart-Thomas elements. The proposed semi-implicit scheme is a good alternative when implicit schemes meet convergence issues.