Quantitative Homogenization of a Cahn--Hilliard System with Source Term in Periodically Perforated Domains

We study qualitative and quantitative homogenization for a Cahn--Hilliard system with a nonconservative source term in a periodically perforated domain.

Using the periodic unfolding method, we derive uniform energy estimates and prove convergence to a homogenized Cahn--Hilliard system whose effective diffusion tensor is characterized by scalar Neumann cell problems on the pore cell.

For the quantitative analysis, we construct first-order corrector approximations by means of a scale-splitting operator, so that the cell correctors are only required to belong to $H^1_{\mathrm{per}}(Y_p)$.

Under $H^2$-regularity of the homogenized solution and well-prepared initial data, we obtain an order $\varepsilon^{1/2}$ corrector estimate: the corrected order-parameter error is controlled in $L^2(0,T;H^1(\Omega_p^\varepsilon))$, while the uncorrected order parameter is controlled in $L^2(0,T;L^2(\Omega_p^\varepsilon))$.

This improves the rate $\varepsilon^{1/4}$ previously established for fourth-order phase-field equations in perforated media, and matches the natural rate for second-order elliptic problems in perforated domains.

The rate reflects the boundary layer caused by incomplete cells near $\partial\Omega$ and improves to order $\varepsilon$ on the flat torus $\mathbb{T}^d$.