Difference methods for computing the Ginzburg-Landau equation in two dimensions

Let W be a bounded, simply connected, regular domain of R N , N \ 2. For 0 < e < 1, let u e : W Q C be a smooth solution of the Ginzburg-Landau equation in W with Dirichlet boundary condition g e , i.e., ## ˛-Du in W, u e =g e on "W.

In this paper, the authors have studied a generalized Ginzburg᎐Landau equation Ž . in two spatial dimensions 2D . They have shown that this equation, under periodic boundary conditions, has the maximal attractor with finite Hausdorff dimension. This rigorously establishes the foundation for further

The Ginzburg᎐Landau-type complex partial differential equations are simplified mathematical models for various pattern formation systems in mechanics, physics, and chemistry. Most work so far concentrates on Ginzburg᎐Landau-type equations Ž . with one spatial dimension 1D . In this paper, the author

The proof of Proposition VI.4 on pages 487-489 in Section VI.3 should be modified as follows. VI.3. Estimates for |N |u e ||, 1 [ p < 2 We follow here closely the argument of [Bethuel-Brezis-He ´lein 2, Lemma X.13]. Let 1 [ p < 2 and set r=|u e |.