Numerical analysis of the cross-diffusion Cahn-Hilliard model in lymphangiogenesis

In this paper, a fully discrete finite element numerical scheme with a stabilizer for the cross-diffusion Cahn--Hilliard model arising in modeling the pre-pattern in lymphangiogenesis is proposed and analysed. The discrete energy dissipation stability and existence of the numerical solution for the scheme are proven. The rigorous error estimate analysis is carried out based on establishing one new $L^{\frac43}(0,T;L^{\frac65}(\Omega))$ norm estimate for nonlinear cross-diffusion term in the error system uniformly in time and spacial step sizes. The convergence of the numerical solution to the solution of the continuous problem is also proven by establishing one new $L^{\frac43}(0,T;W^{1,\frac65}(\Omega))$ norm estimate for the approximating chemical potential sequence, which overcomes the difficulty that here we can not obtain $l^2(0,T;H^1(\Omega))$ estimate for the numerical chemical potential uniformly in time and spacial step sizes because of the nonlinear cross-diffusion characterization of the Cahn--Hilliard cross-diffusion model. Our investigation reveals the connection between this cross-diffusion model and the Cahn--Hilliard equation and verifies the effectiveness of the numerical method. In addition, numerical results are presented to illustrate our theoretical analysis.