In this paper we consider the hyperbolic relaxation of the Cahn-Hilliard equation ruling the evolution of the relative concentration $u$ of one component of a binary alloy system located in a bounded and regular domain $\Omega$ of $\Bbb R^3$. This equation is characterized by the presence of the additional inertial term $\epsilon u_{tt}$ that accounts for the relaxation of the diffusion flux. For this equation we address the problem of the long time stability from the point of view of global attractors. The main difficulty in dealing with this system is the low regularity of its weak solutions, which prevents us from proving a uniqueness result and a proper energy identity for the solutions. We overcome this difficulty by using a density argument based on a Faedo-Galerkin approximation scheme and J. M. Ball's recent theory of generalized semiflows. Moreover, we address the problem of the approximation of the attractor of the continuous problem with the one of the Faedo-Galerkin scheme. Finally, we show that the same type of results hold also for the damped semilinear wave equation when the nonlinearity $\phi$ is not Lipschitz continuous and has a super critical growth.
On the hyperbolic relaxation of the Cahn-Hilliard equation in 3D: approximation and long time behaviour.
SEGATTI, ANTONIO GIOVANNI
2007-01-01
Abstract
In this paper we consider the hyperbolic relaxation of the Cahn-Hilliard equation ruling the evolution of the relative concentration $u$ of one component of a binary alloy system located in a bounded and regular domain $\Omega$ of $\Bbb R^3$. This equation is characterized by the presence of the additional inertial term $\epsilon u_{tt}$ that accounts for the relaxation of the diffusion flux. For this equation we address the problem of the long time stability from the point of view of global attractors. The main difficulty in dealing with this system is the low regularity of its weak solutions, which prevents us from proving a uniqueness result and a proper energy identity for the solutions. We overcome this difficulty by using a density argument based on a Faedo-Galerkin approximation scheme and J. M. Ball's recent theory of generalized semiflows. Moreover, we address the problem of the approximation of the attractor of the continuous problem with the one of the Faedo-Galerkin scheme. Finally, we show that the same type of results hold also for the damped semilinear wave equation when the nonlinearity $\phi$ is not Lipschitz continuous and has a super critical growth.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.