A mixed formulation of the Stefan problem with surface tension

Abstract: A dual formulation and finite element method is proposed and analyzed for simulating the Stefan problem with surface tension. The method uses a mixed form of the heat equation in the solid and liquid (bulk) domains, and imposes a weak formulation of the interface motion law (on the solidliquid interface) as a constraint. The basic unknowns are the heat fluxes and temperatures in the bulk, and the velocity and temperature on the interface. The formulation, as well as its discretization, is viewed as a saddle po… Show more

“…The formulation (4.16) was shown to be well-posed, by verifying coercivity and inf-sup conditions [10,12], in our previous work [16] with the chosen norms (4.14), (4.15). Furthermore, we showed that the semi-discrete system (4.5), (4.6) satisfies both an a priori stability bound in time and a conservation law [16].…”

“…interface motion law appears as a constraint in the system of equations with a balancing Lagrange multiplier that represents the interface temperature. Our work recently appeared in [16], where we showed that our method satisfies an a priori energy bound for the time semi-discrete and fully discrete cases. It also satisfies a conservation law for the thermal energy.…”

“…The purpose of the current paper is to give more details on the implementation of the method in [16], as well as derive preliminary (semi-discrete) error estimates between the time semi-discrete and fully discrete solutions over one time step. We discuss the difficulties in obtaining a full error analysis at the beginning of Section 6.…”

“…The particular mathematical model we consider can be found in [6,16,32]. In this section, we present the strong form of the Stefan problem in non-dimensional form.…”

“…We give the time semi-discrete weak formulation of (2.2), (2.3) which was originally presented in our previous work [16]…”

Semi-discrete error estimates and implementation of a mixed method for the Stefan problem

“…The formulation (4.16) was shown to be well-posed, by verifying coercivity and inf-sup conditions [10,12], in our previous work [16] with the chosen norms (4.14), (4.15). Furthermore, we showed that the semi-discrete system (4.5), (4.6) satisfies both an a priori stability bound in time and a conservation law [16].…”

“…interface motion law appears as a constraint in the system of equations with a balancing Lagrange multiplier that represents the interface temperature. Our work recently appeared in [16], where we showed that our method satisfies an a priori energy bound for the time semi-discrete and fully discrete cases. It also satisfies a conservation law for the thermal energy.…”

“…The purpose of the current paper is to give more details on the implementation of the method in [16], as well as derive preliminary (semi-discrete) error estimates between the time semi-discrete and fully discrete solutions over one time step. We discuss the difficulties in obtaining a full error analysis at the beginning of Section 6.…”

“…The particular mathematical model we consider can be found in [6,16,32]. In this section, we present the strong form of the Stefan problem in non-dimensional form.…”

“…We give the time semi-discrete weak formulation of (2.2), (2.3) which was originally presented in our previous work [16]…”

Semi-discrete error estimates and implementation of a mixed method for the Stefan problem

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