In this paper we analyse a finite volume scheme for a nonlocal version of the Shigesada-Kawazaki-Teramoto (SKT) cross-diffusion system. We prove the existence of solutions to the scheme, derive qualitative properties of the solutions and prove its convergence. The proofs rely on a discrete entropy-dissipation inequality, discrete compactness arguments, and on the novel adaptation of the so-called duality method at the discrete level. Finally, thanks to numerical experiments, we investigate the influence of the nonlocality in the system: on convergence properties of the scheme, as an approximation of the local system and on the development of diffusive instabilities
An implicit Euler finite-volume scheme for a cross-diffusion system modeling biofilm growth is analy...
Abstract. We exploit a recently developed nonlocal vector calculus to provide a variational analysis...
40 pagesWe consider conservative cross-diffusion systems for two species where individual motion rat...
In this paper we analyse a finite volume scheme for a nonlocal version of the Shigesada-Kawazaki-Ter...
In this paper we analyse a finite volume scheme for a nonlocal version of the Shigesada–Kawazaki–Ter...
International audienceAn implicit Euler finite-volume scheme for an n-species population cross-diffu...
International audienceIn this work we present the convergence of a positivity preserving semi-discre...
The main goal of this paper is to propose a convergent finite volume method for a reactionâeuro"diff...
In this paper, we consider a reaction-di usion system describing three interacting species in the fo...
In this thesis we present some results on cross-diffusion and nonlocal interaction. In the first par...
International audienceIn this paper, we propose a nonlocal cross-diffusion-fluid system describing t...
The aim of this work is to propose a provably convergent finite volume scheme for the so-called Stef...
Systems describing the long-range interaction between individuals have attracted a lot of attention ...
We study a nonlocal two species cross-interaction model with cross-diffusion. We propose a positivit...
Implementation (in the Julia language) of the finite volume scheme proposed in Clément Cancès, Jean...
An implicit Euler finite-volume scheme for a cross-diffusion system modeling biofilm growth is analy...
Abstract. We exploit a recently developed nonlocal vector calculus to provide a variational analysis...
40 pagesWe consider conservative cross-diffusion systems for two species where individual motion rat...
In this paper we analyse a finite volume scheme for a nonlocal version of the Shigesada-Kawazaki-Ter...
In this paper we analyse a finite volume scheme for a nonlocal version of the Shigesada–Kawazaki–Ter...
International audienceAn implicit Euler finite-volume scheme for an n-species population cross-diffu...
International audienceIn this work we present the convergence of a positivity preserving semi-discre...
The main goal of this paper is to propose a convergent finite volume method for a reactionâeuro"diff...
In this paper, we consider a reaction-di usion system describing three interacting species in the fo...
In this thesis we present some results on cross-diffusion and nonlocal interaction. In the first par...
International audienceIn this paper, we propose a nonlocal cross-diffusion-fluid system describing t...
The aim of this work is to propose a provably convergent finite volume scheme for the so-called Stef...
Systems describing the long-range interaction between individuals have attracted a lot of attention ...
We study a nonlocal two species cross-interaction model with cross-diffusion. We propose a positivit...
Implementation (in the Julia language) of the finite volume scheme proposed in Clément Cancès, Jean...
An implicit Euler finite-volume scheme for a cross-diffusion system modeling biofilm growth is analy...
Abstract. We exploit a recently developed nonlocal vector calculus to provide a variational analysis...
40 pagesWe consider conservative cross-diffusion systems for two species where individual motion rat...