Add to ORKGWe study a two-scale coupled system consisting of a macroscopic elliptic equation and a microscopic parabolic equation. This system models the interplay between a gas and liquid close to equilibrium within a porous medium with distributed microstructures. We use formal homogenization arguments to derive the target system. We start by proving well-posedness and inverse estimates for the two-scale system. We follow up by proposing a Galerkin scheme which is continuous in time and discrete in space, for which we obtain well-posedness, a priori error estimates and convergence rates. Finally, we propose a numerical error reduction strategy by refining the grid based on residual error estimators
The present thesis is devoted to the homogenization of certain elliptic and parabolic partial differ...
A Galerkin approach for a class of multiscale reaction–diffusion systems with nonlinear coupling bet...
Abstract. Multiscale partial differential equations (PDEs) are difficult to solve by traditional num...
We study a two-scale coupled system consisting of a macroscopic elliptic equation and a microscopic ...
In this paper, we study the numerical approximation of a coupled system of elliptic–parabolic equati...
An upscaled elliptic-parabolic system of partial differential equations describing the multiscale f...
In this dissertation, parabolic-pseudoparabolic equations are proposed to couple chemical reactions,...
Motivated by the study of the hypoxia problem in cancerous tissues, we propose a system of coupled p...
We study a two-scale reaction-diffusion system with nonlinear reaction terms and a nonlinear transmi...
This paper aims at an accurate and efficient computation of effective quantities, e.g. the homogeniz...
Multiscale problems, such as modelling flows through porous media or predicting the mechanical prope...
The focus of this thesis is the theory of periodic homogenization of partial differential equations ...
We present a numerical scheme for the approximation of the system of partial differential equations...
We consider the homogenization of a coupled system of PDEs describing flows in highly heterogeneous ...
Abstract. The heterogeneous multiscale method (HMM) is applied to various parabolic prob-lems with m...
The present thesis is devoted to the homogenization of certain elliptic and parabolic partial differ...
A Galerkin approach for a class of multiscale reaction–diffusion systems with nonlinear coupling bet...
Abstract. Multiscale partial differential equations (PDEs) are difficult to solve by traditional num...
We study a two-scale coupled system consisting of a macroscopic elliptic equation and a microscopic ...
In this paper, we study the numerical approximation of a coupled system of elliptic–parabolic equati...
An upscaled elliptic-parabolic system of partial differential equations describing the multiscale f...
In this dissertation, parabolic-pseudoparabolic equations are proposed to couple chemical reactions,...
Motivated by the study of the hypoxia problem in cancerous tissues, we propose a system of coupled p...
We study a two-scale reaction-diffusion system with nonlinear reaction terms and a nonlinear transmi...
This paper aims at an accurate and efficient computation of effective quantities, e.g. the homogeniz...
Multiscale problems, such as modelling flows through porous media or predicting the mechanical prope...
The focus of this thesis is the theory of periodic homogenization of partial differential equations ...
We present a numerical scheme for the approximation of the system of partial differential equations...
We consider the homogenization of a coupled system of PDEs describing flows in highly heterogeneous ...
Abstract. The heterogeneous multiscale method (HMM) is applied to various parabolic prob-lems with m...
The present thesis is devoted to the homogenization of certain elliptic and parabolic partial differ...
A Galerkin approach for a class of multiscale reaction–diffusion systems with nonlinear coupling bet...
Abstract. Multiscale partial differential equations (PDEs) are difficult to solve by traditional num...