\documentclass[reqno]{amsart}
\usepackage{hyperref}

\AtBeginDocument{{\noindent\small
{\em Electronic Journal of Differential Equations},
Vol. 2007(2007), No. 28, pp. 1--12.\newline
ISSN: 1072-6691. URL: http://ejde.math.txstate.edu or http://ejde.math.unt.edu
\newline ftp ejde.math.txstate.edu  (login: ftp)}
\thanks{\copyright 2007 Texas State University - San Marcos.}
\vspace{9mm}}

\begin{document}
\title[\hfilneg EJDE-2007/28\hfil Existence of solutions]
{Existence of solutions to a phase-field model with phase-dependent
heat absorption}

\author[G. Planas\hfil EJDE-2007/28\hfilneg]
{Gabriela Planas}

\address{Gabriela Planas \newline
 Departamento de Matem{\'a}tica \\
 Instituto de Ci\^encias Matem\'aticas e de Computa\c{c}\~ao\\
 Universidade de S\~ao Paulo - Campus de S\~ao Carlos \\
 Caixa Postal 668, S{\~a}o Carlos, SP 13560-970, Brazil}
\email{gplanas@icmc.usp.br}

\thanks{Submitted November 16, 2006. Published February 12, 2007.}
\subjclass[2000]{35K55, 80A22, 82B26, 35B65}
\keywords{Phase transitions; parabolic system; phase-field models}

\begin{abstract}
 We consider a phase-field model for a phase change process with
 phase-dependent heat absorption. This model describes the behaviour
 of films exposed to radiative heating, where the film can change
 reversibly between amorphous and crystalline states. Existence and
 uniqueness of solutions as well as stability are established.
 Moreover, a maximum principle is proved for the phase-field
 equation.
\end{abstract}

\maketitle
\numberwithin{equation}{section}
\newtheorem{theorem}{Theorem}[section]
\newtheorem{remark}[theorem]{Remark}
\newtheorem{proposition}[theorem]{Proposition}
\newtheorem{corollary}[theorem]{Corollary}

\section{Introduction}

In recent years the phase-field method has emerged as a powerful
computational approach to modelling and predicting a range of phase
transitions and complex growth structures occurring during
solidification. This has spurred many articles using this approach
and proposing several mathematical models. Phase-field models have
also been developed to treat both pure materials and binary alloys;
as examples of papers where mathematical analysis of such models is
performed, we single out
\cite{Boldrini,Caginalp,ColliHoffmann,Colli,Hoffman,Moro,Rappaz,Stefanelli},
where existence of solutions is investigated for various types of
nonlinearities.

We consider in this paper a phase-field model for a phase change
process with phase-dependent heat absorption. Such a model was
proposed by Blyuss et al. \cite{Blyuss} to model the
behaviour of films exposed to radiative heating, where the film can
change reversibly between amorphous and crystalline states. The
models adopted so far have neglected the difference in the response
of different phases to external heat sources considering only
external forces which do not depend neither on the phase-field nor
on the temperature. To be specific, the model we consider
incorporates illumination and phase-dependent absorption in the
equation for the temperature, and this influences the phase change
process, as described by the phase-field equation.

This model can be expressed as the following coupled system
\begin{gather}\label{originalpfe}
 \phi_t  -  \epsilon^2 \Delta \phi  =  \phi - \phi^3  +
\dfrac{(\theta_M -\theta)}{\delta}\hat{\lambda}(1-\phi^2)^2  \quad
\mbox{in } \Omega \times (0,T),
\\ \label{originalte}
 \theta_t- K \Delta \theta  =   \frac{\delta}{2}\phi_t+
\big[a_1 + a_{-1} + (a_1-a_{-1})\phi\big]\frac{I}{2} + b (\theta_a -\theta)
 \quad \mbox{in } \Omega \times (0,T),
\\
\frac{\partial \phi}{\partial n} = 0 , \quad \frac{\partial
\theta}{\partial n} = 0, \quad \mbox{on }
\partial \Omega \times (0,T),
\\ \label{dados}
\phi(0) = \phi_0 , \quad \theta (0) = \theta_0 \quad \mbox{in }
\Omega.
\end{gather}
Here $\Omega$ is an open bounded domain of $\mathbb{R}^N$,
$N = 2,3$, with smooth boundary $\partial \Omega$ and $ T >0$.
The order parameter (phase-field) $\phi$ is the state variable characterizing
the different phases; the convection adopted is that $ \phi \in
[-1,1]$, with the lower limit $ \phi =-1$ corresponding to pure melt
while $ \phi =1 $ represents solid. The function $\theta$ represents
the temperature of a material which melts at $ \theta = \theta_M$.
The interface thickness $ \epsilon $ is a small parameter and $
\hat{\lambda}$ is a measure of the strength of coupling between the
phase field and a dimensionless temperature field $ (\theta -
\theta_M)/\delta$, where $\delta  $ is given by $ \delta = L/C_p$,
being $L>0$ the latent heat and $ C_p >0 $ the specific heat at
constant pressure. For simplicity of exposition it will be assumed
$\hat{\lambda} = 1 $. The constant
$ K >0 $ denotes a thermal diffusivity; $ a_{\pm 1}$ are the radiative
absorption
coefficients for the solid and molten phases; $ I $ is the rate of
incident heating; $ b $ is a thermal emission coefficient and
$\theta_a$ is the ambient temperature.



Our aim is to prove existence and uniqueness of solutions as well as
stability. Moreover, a maximum principle is established for the
phase-field equation which ensures that $ \phi $ stays between $-1$
and $ 1 $ as long as the initial data $ \phi_0 $ does. We observe
that this bound on the phase-field will allow us to show a stability
result and, subsequently, the uniqueness of the solution. Existence
of solutions will be obtained by using an auxiliary problem. The
approach is to modify the problem by introducing an appropriate
truncation of $ (1-\phi^2)^2$. This auxiliary problem will then be
studied by using fixed point arguments.

Standard notation will be used. For a given fixed $T > 0 $, we
denote $Q = \Omega \times (0,T)$ and we consider the following
spaces, for $ q \geq 1$,
\[
W^{2,1}_q (Q) = \{ w \in L^q(Q) : D_xw,D^2_xw \in L^q(Q),
w_t \in L^q(Q) \}.
\]


The outline of this paper is as follows. In the next section we
study an auxiliary problem. The last section is devoted to prove the
well-posedness of problem \eqref{originalpfe}-\eqref{dados}. First,
we study the existence of solutions, secondly we establish a
stability result which will give us uniqueness at the same time and,
finally, a result of regularity of the solution will be obtained by
applying $L^p$-theory of parabolic linear equations together with
bootstrapping arguments.



\section{An auxiliary problem}

In this section, we introduce an auxiliary problem related to
\eqref{originalpfe}-\eqref{dados} for which we will prove a result
of existence of solutions by using Leray-Schauder's fixed point
theorem \cite{Friedman}.

Let $ \Pi $ be the function
\[ \Pi(r) =
\begin{cases}
-1, & r < -1 \\
r, & -1 \leq r \leq 1 \\
1, & r > 1\,.
\end{cases}
\]
Consider the  problem
\begin{gather}
 \phi_t -  \epsilon^2 \Delta \phi   =
  \phi - \phi^3  + \dfrac{(\theta_M -\theta)}{\delta}(1-\Pi(\phi)^2)^2
\quad \mbox{in } Q, \label{regularpfe} \\
 \theta_t - K \Delta \theta + b \theta  =   \frac{\delta}{2} \phi_t  + \alpha
 \phi  + \beta
\quad \mbox{in } Q,  \label{regularte} \\
\frac{\partial \phi}{\partial n} = 0 ,\quad   \frac{\partial \theta}
{\partial n} = 0,
 \quad  \mbox{on } \partial \Omega \times (0,T), \\
\phi(0) = \phi_0 , \quad \theta(0) = \theta_0, \quad \mbox{in }
\Omega, \label{regulardados}
\end{gather}
where $ \alpha = (a_1-a_{-1})\dfrac{I}{2} $ and $ \beta = (a_1 +
a_{-1}) \dfrac{I}{2} + b \theta_a$.

We then have the following existence result.

\begin{proposition} \label{regularizado}
Let $(\phi_0,\theta_0) \in H^{1+\gamma}(\Omega) \times
H^{1+\gamma}(\Omega) $, $1/2 < \gamma \leq 1$, satisfying the
compatibility condition $\displaystyle \frac{\partial
\phi_0}{\partial n} =\frac{\partial \theta_0 }{\partial n} =0 $ a.e.
on $\partial \Omega$. Then there exists $ (\phi , \theta) \in
W^{2,1}_2(Q)\times W^{2,1}_2(Q) $ solution to problem
\eqref{regularpfe}-\eqref{regulardados} for any fixed
$T> 0$, which verifies the estimate
\begin{equation} \label{regularest}
\|\phi\|_{W^{2,1}_2(Q)} + \|\theta\|_{W^{2,1}_2(Q)} \leq C
\bigl(\|\phi_0\|_{H^1(\Omega)} + \|\theta_0\|_{H^1(\Omega)} +
1\bigr),
\end{equation}
where $C$ depends on $ \Omega$, and some physical parameters.
\end{proposition}

\begin{proof}
In order to apply Leray-Schauder's fixed  point theorem we consider
the following family of operators, indexed by the parameter $0 \leq
\lambda \leq 1$,
\[
\mathcal{T}_{\lambda} : B \to B,
\]
where $B$ is the Banach space
\[
B = L^2(Q) \times L^2(Q) ,
\]
and is defined as follows: given $(\hat{\phi}, \hat{\theta}) \in B$,
let $\mathcal{T}_\lambda(\hat{\phi}, \hat{\theta})=(\phi, \theta)$,
where $(\phi, \theta)$ is obtained by solving the problem
\begin{gather}
 \phi_t  -  \epsilon^2 \Delta \phi   -  ( \phi - \phi^3 )
= \lambda \dfrac{(\theta_M-
\hat{\theta})}{\delta}(1-\Pi(\hat{\phi})^2)^2 \quad \mbox{in } Q, \label{auxpfe} \\
  \theta_t  - K \Delta \theta + b \theta  =   \frac{\delta}{2} \phi_t + \alpha
 \phi  + \beta
    \quad \mbox{in } Q,  \label{auxte} \\
\frac{\partial \phi}{\partial n} = 0 ,\quad  \frac{\partial \theta}
{\partial n} = 0
 \quad  \mbox{on } \partial \Omega \times (0,T), \label{auxbound}\\
\phi(0) = \phi_0 , \quad \theta(0) = \theta_0 \quad \mbox{in } \Omega.
\label{auxdados}
\end{gather}

Before we prove that $\mathcal{T}_\lambda$ is well defined, we
observe that clearly $(\phi, \theta)$ is a solution of
\eqref{regularpfe}-\eqref{regulardados} if and only if it is a fixed
point of the operator $\mathcal{T}_1$.

To verify that the operator $\mathcal{T}_\lambda$ is well defined,
observe that since $\hat{\theta}\in L^2(Q)$ and
$|(1-\Pi(\hat{\phi})^2)^2| \leq 1$, we infer from
 \cite[Theorem 2.1]{Hoffman} that there is a unique solution $\phi$ of equation
\eqref{auxpfe} with $\phi \in W^{2,1}_2(Q) $ satisfying the first of
the boundary conditions \eqref{auxbound}.

Since $\phi $ and $ \phi_t \in L^2(Q), $ according to $L^p$-theory
of parabolic equations
\cite[Theorem 9.1]{Lady} there is a unique solution $\theta $ of
equation \eqref{auxte} with $\theta \in W^{2,1}_2(Q)$ satisfying the
second of the boundary conditions \eqref{auxbound}.


Therefore, for each $\lambda \in [0,1]$, the mapping $\mathcal{T}_{\lambda} $
is well defined from $B$ into $B$.

To prove continuity of $\mathcal{T}_{\lambda}$, let $ (\hat{\phi}_n,
\hat{\theta}_n) \in B$ strongly converging to $(\hat{\phi},
\hat{\theta}) \in B$; for each $n$, let $(\phi_n, \theta_n)$ the
corresponding solution of problem
\begin{gather}
{\phi_n}_t  -  \epsilon^2 \Delta \phi_n   -  ( \phi_n - \phi_n^3 )
=    \lambda \dfrac{(\theta_M-\hat{\theta}_n
)}{\delta}(1-\Pi(\hat{\phi}_n)^2)^2 \quad \mbox{in } Q, \label{npfe} \\
  {\theta_n}_t - K \Delta \theta_n + b \theta_n
=  \frac{\delta}{2} {\phi_n}_t + \alpha
 \phi_n  + \beta    \quad \mbox{in } Q,  \label{nte} \\
\frac{\partial \phi_n}{\partial n} = 0 ,\quad \frac{\partial \theta_n}
{\partial n} = 0
 \quad  \mbox{on } \partial \Omega \times (0,T), \\
\phi_n(0) = \phi_0 , \quad \theta_n(0) = \theta_0 \quad
 \mbox{in }\Omega. \label{ndados}
\end{gather}

Next, we show that the sequence $(\phi_n, \theta_n)$ converges
strongly to $(\phi, \theta) = \mathcal{T}_{\lambda}( \hat{\phi},
\hat{\theta}) $ in $B$. For that purpose, we will obtain estimates,
uniformly with respect to $n$, for $(\phi_n, \theta_n)$. We denote
by $ C_i $ any positive constant independent of $n$.

We multiply \eqref{npfe} successively by $\phi_n$, ${\phi_n}_t$ and
$-\Delta \phi_n$, and integrate over $ \Omega \times (0,t)$. After
integration by parts and the use of H\"{o}lder and Young
inequalities, we obtain the following three estimates
\begin{gather}
\begin{aligned}
\frac{1}{2} \int_{\Omega} | \phi_n|^2 dx  + & \int_0^t
\int_{\Omega}\left(\epsilon^2 | \nabla \phi_n |^2 + |\phi_n|^4
\right)\,dx\,ds \\
&\leq   C_1 + C_2 \int_0^t \int_{\Omega} \left( |
\hat{\theta}_n |^2 +  | \phi_n|^2 \right) \,dx\,ds,
\end{aligned}\label{a}
\\
\begin{aligned}
\frac{1}{2} \int_0^t \int_{\Omega}| {\phi_n}_t |^2 \,dx\,ds + &
\int_{\Omega} \left( \frac{\epsilon^2}{2} | \nabla \phi_n|^2 +
\frac{|\phi_n|^4}{4} - \frac{|\phi_n|^2}{2} \right)dx \\
&\leq  C_1 + C_2 \int_0^t \int_{\Omega} | \hat{\theta}_n |^2  \,dx\,ds ,
\end{aligned}\label{b}
\\
\begin{aligned}
\frac{1}{2}\int_{\Omega}| \nabla \phi_n |^2 dx + &
\frac{\epsilon^2}{2} \int_0^t \int_{\Omega} | \Delta \phi_n |^2
\,dx\,ds
\\
&\leq  C_1 + C_2 \int_0^t \int_{\Omega} \left( | \nabla \phi_n |^2  +
 | \hat{\theta}_n |^2  \right) \,dx\,ds.
\end{aligned}\label{c}
\end{gather}
By multiplying \eqref{b} by $ \frac{1}{2} $ and adding the result to
\eqref{a} we find
\[
\int_{\Omega} \left( | \phi_n |^2   +   | \nabla \phi_n |^2 +
|\phi_n|^4 \right) dx  \leq  C_1 + C_2 \int_0^t \int_{\Omega} \left(
| \hat{\theta}_n |^2 +  | \phi_n|^2 \right) \,dx\,ds.
\]
Since $ \|  \hat{\theta}_n \|_{L^2(Q)} $ is bounded independent of
$n$, by using Gronwall's lemma we deduce that
\begin{equation} \label{e}
\| \phi_n \|_{L^{\infty}(0,T; H^1(\Omega))} \leq C_1.
\end{equation}
Then, thanks to estimates (\ref{a})-(\ref{c}) we arrive at
\begin{equation} \label{f}
\| \phi_n \|_{L^2(0,T; H^2(\Omega))} + \| {\phi_n}_t \|_{L^2(Q)} \leq C_1.
\end{equation}
Next, from $L^p$-theory of parabolic equations applied to equation
\eqref{nte} we have
\begin{equation} \label{h} \| \theta_n
\|_{W^{2,1}_2(Q)}  \leq C_1 ( \|\theta_0\|_{H^1(\Omega)} +
\|{\phi_n}_t \|_{L^2(Q)} + \|\phi_n \|_{L^2(Q)}+1).
\end{equation}
We now infer from \eqref{e},\eqref{f} and \eqref{h} that the
sequence $(\phi_n, \theta_n) $ is bounded in $ W^{2,1}_2(Q) $ and in
\[
W = \left \{ v \in L^{\infty}(0,T; H^1(\Omega)),\, v_t \in L^2(0,T;
L^2(\Omega)) \right\}.
\]
Since $W^{2,1}_2(Q)$ is compactly embedded in
$L^2(0,T;H^1(\Omega))$ and $W$ in $ C([0,T];L^2(\Omega))$
\cite[Corollary 4]{Simon}, it follows that there exist
\[
\phi, \, \theta  \in  L^2(0,T; H^2(\Omega)) \cap  L^{\infty}(0,T;
H^1(\Omega)) \quad \mbox{with } \phi_t,\, \theta_t \in L^2(Q),
 \]
and a subsequence of $ (\phi_n, \theta_n) $ (which we still denote
by $ (\phi_n, \theta_n)$), such that, as $ n \to + \infty$,
\begin{equation} \label{conv}
\begin{gathered}
(\phi_n,  \theta_n)  \to  (\phi, \theta) \quad \mbox{in }
\bigl(L^2(0,T;H^1(\Omega)) \cap C([0,T];L^2(\Omega))\bigr)^2
\quad \mbox{strongly, }\\
(\phi_n, \theta_n)  \rightharpoonup  (\phi,\, \theta)  \quad \mbox{in }
\bigl(W^{2,1}_2(Q)\bigr)^2 \quad \mbox{weakly.}
\end{gathered}
\end{equation}

It now remains to pass to the limit as $n$ tends to $ +\infty$ in
(\ref{npfe})-(\ref{ndados}). Since the embedding of $ W^{2,1}_2(Q)$
into $ L^9(Q) $ is compact \cite{Lions}, we infer that $ \phi_n^3 $
converges to $ \phi^3 $ in $L^2(Q). $ Moreover, since
$(1-\Pi(\cdot)^2)^2 $ is a bounded Lipschitz continuous function and
$\hat{\phi_n}$ converges to $\hat{\phi} $ in $ L^2(Q)$, we have that
$ (1-\Pi(\hat{\phi_n})^2)^2$ converges to $ (1-\Pi(\hat{\phi})^2)^2$
in $ L^p(Q) $ for any $ p \in [1,\infty)$. We then pass to the limit
in \eqref{npfe} and get \eqref{auxpfe}.

From convergence \eqref{conv}, it is easy to pass to the limit in
\eqref{nte} and conclude that \eqref{auxte} holds almost everywhere.

Therefore $\mathcal{T}_{\lambda}$ is continuous for all
$ 0 \leq \lambda \leq 1$. At the same time, $\mathcal{T}_{\lambda}$ is
bounded in $ W^{2,1}_2(Q)\times W^{2,1}_2(Q) $ but,  the embedding
of this space in $B$ is compact. Hence, $\mathcal{T}_{\lambda}$ is a
compact operator for each $\lambda \in [0,1]$.

 To prove that for $(\hat{\phi}, \hat{\theta})$ in a bounded set of $B$,
 $T_{\lambda} $ is uniformly
continuous with respect to $\lambda$, let $ 0 \leq \lambda_1,
\lambda_2 \leq 1 $ and $(\phi_i, \theta_i)\, (i=1,2)$ be the
corresponding solutions of \eqref{auxpfe}-\eqref{auxdados}. We
observe that $\phi= \phi_1 - \phi_2 $ and $ \theta = \theta_1 -
\theta_2 $ satisfy the  problem
\begin{gather}
\begin{aligned}
 \phi_t  -  \epsilon^2 \Delta \phi   = &
  \phi (1- (\phi_1^2 + \phi_1 \phi_2 + \phi_2^2) ) \\
 & +   (\lambda_1 - \lambda_2)  \Bigl( \dfrac{(\theta_M-
 \hat{\theta})}{\delta}(1-\Pi(\hat{\phi})^2)^2  \Bigr) \mbox{ in } Q,
\end{aligned}\label{lpfe}
\\
 \theta_t  - K \Delta \theta + b \theta  =   \frac{\delta}{2} \phi_t + \alpha
 \phi \quad \mbox{in } Q, \label{lte}
\\
\frac{\partial \phi}{\partial n} = 0 ,\quad  \frac{\partial \theta}
{\partial n} = 0
 \quad \mbox{on } \partial \Omega \times (0,T),
\\
\phi(0) = 0 , \quad \theta(0) = 0  \quad \mbox{in } \Omega.
\label{ldados}
\end{gather}
We remark that $d:= \phi_1^2 + \phi_1 \phi_2 + \phi_2^2 \geq 0$.
Now, multiply equation \eqref{lpfe} by $\phi$ and integrate over
$\Omega \times(0,t);$ after integration by parts and the use of
H\"older and Young inequalities we obtain
\begin{align*}
\int_{\Omega} | \phi |^2 dx + & \int_0^t \int_{\Omega} | \nabla \phi
|^2 \,dx\,ds
\\
& \leq  C_1  \int_0^t \int_{\Omega} | \phi |^2 \,dx\,ds
 +  C_2| \lambda_1 - \lambda_2 |^2 \int_0^t
\int_{\Omega} (| \hat{\theta} |^2  +1 )\,dx\,ds .
\end{align*}
By applying Gronwall's lemma we arrive at
\begin{equation} \label{o}
\| \phi \|^2_{L^{\infty} (0,T; L^2(\Omega))} + \| \phi \|^2_{L^2(0,T; H^1(\Omega))}
 \leq  C_1 \, | \lambda_1 - \lambda_2 |^2.
\end{equation}
Multiplying \eqref{lpfe} by $ \phi_t $ and using H\"older
inequality, we get
\begin{align*}
\int_0^t \int_{\Omega} | \phi_t |^2 \,dx\,ds
 + & \frac{\epsilon^2}{2} \int_{\Omega} | \nabla \phi  |^2 dx\\
& \leq    C_1  \int_0^t \int_{\Omega} | \phi |^2 \,dx\,ds
+ \frac{1}{2}  \int_0^t \int_{\Omega} | \phi_t |^2 \,dx\,ds
\\
&\quad +   C_2 \Big( \int_0^t \int_{\Omega} | \phi
|^{10/3} \,dx\,ds \Big)^{3/5} \Big(\int_0^t \int_{\Omega} | d |^5
\,dx\,ds \Big)^{2/5}
\\
&\quad +  C_3| \lambda_1 - \lambda_2 |^2 \int_0^t
\int_{\Omega} ( | \hat{\theta} |^2 + 1 ) \,dx\,ds .
\end{align*}
Since $ W^{2,1}_2(Q) \hookrightarrow L^{10}(Q) $, the following
interpolation inequality holds
\[
\| \phi \|^2_{L^{10/3}(Q)} \leq \eta \, \| \phi \|^2_{W^{2,1}_2(Q)} + \tilde{C} \, \|
\phi \|^2_{L^2(Q)}  \quad \mbox{for all } \eta > 0.
\]
Moreover, since $\| d \|_{L^5(Q)} \leq C$, with $C$ depending on $\|
\phi_i \|_{L^{10}(Q)},\, i =1,2$, by rearranging the terms in the
last inequality, we obtain
\begin{equation} \label{r}
\begin{aligned}
 \int_0^t \int_{\Omega} | \phi_t |^2 \,dx\,ds  +
  \int_{\Omega} | \nabla \phi  |^2 dx
\leq &  C_1  \int_0^t \int_{\Omega} | \phi |^2 \,dx\,ds + C_2  \eta
 \| \phi \|^2_{W^{2,1}_2(Q)} \\
&  +   C_3 | \lambda_1 - \lambda_2 |^2 \int_0^t \int_{\Omega} ( |
\hat{\theta} |^2 + 1 ) \,dx\,ds .
\end{aligned}
\end{equation}
Multiplying \eqref{lpfe} by $- \Delta \phi$, we infer in a
similar way that
\begin{equation} \label{s}
\begin{aligned}
\int_{\Omega} | \nabla \phi |^2 dx   +  &\int_0^t \int_{\Omega} |
\Delta \phi |^2 dx ds\\
&\leq    C_1  \int_0^t \int_{\Omega}\left( | \phi |^2 +  | \nabla
\phi |^2 \right) \,dx\,ds
 +  C_2  \eta  \| \phi \|^2_{W^{2,1}_2(Q)} \\
&\quad +   C_3 | \lambda_1 - \lambda_2 |^2  \int_0^t \int_{\Omega}
( | \hat{\theta} |^2 + 1 ) \,dx\,ds .
\end{aligned}
\end{equation}
By taking $\eta > 0 $ small enough and considering (\ref{o}), we
conclude from (\ref{r}) and (\ref{s}) that
\begin{equation} \label{t}
\| \phi \|^2_{W^{2,1}_2(Q)}  + \| \phi \|^2_{L^{\infty}(0,T;H^1(\Omega))}
\leq C_1  |\lambda_1 - \lambda_2 |^2.
\end{equation}
Next, by multiplying \eqref{lte} by $\theta$, integrating over
$\Omega\times (0,t)$ and using H\"older inequality we have
\[
\int_{\Omega} | \theta |^2 dx  +
\int_0^t \int_{\Omega} | \nabla \theta |^2 \,dx\,ds \leq  C_1
\int_0^t\int_{\Omega}( | \phi_t |^2  + | \phi |^2+ | \theta|^2 ) \,dx\,ds .
\]
Thus, by using Gronwall's lemma and \eqref{t}, we infer that
\begin{equation} \label{u}
\| \theta \|^2_{L^{\infty}(0,T; L^2(\Omega))} \leq C_1 \,  | \lambda_1 - \lambda_2 |^2.
\end{equation}
It follows from \eqref{t} and \eqref{u} that
$\mathcal{T}_{\lambda} $ is uniformly continuous with respect to
$\lambda$ on bounded sets of $B$.

Now we  estimate the set of all fixed points of
$\mathcal{T}_{\lambda}$. Let $ (\phi, \theta) \in B $ be such a
fixed point, i.e. a solution of the problem
\begin{gather}
 \phi_t  -  \epsilon^2 \Delta \phi   -(
 \phi - \phi^3)  =  \lambda  \dfrac{(\theta_M
-\theta)}{\delta}(1-\Pi(\phi)^2)^2 \quad \mbox{in } Q,
\label{fixpfe}
\\
\theta_t - K \Delta \theta + b \theta  =   \frac{\delta}{2} \phi_t
+ \alpha  \phi  + \beta \quad \mbox{in } Q,  \label{fixte}
\\
\frac{\partial \phi}{\partial n} = 0 ,\quad   \frac{\partial
\theta}{\partial n }= 0
 \quad \hfill \mbox{on } \partial \Omega \times (0,T),
\\
\phi(0) = \phi_0 , \quad \theta(0) = \theta_0  \quad \mbox{in }
\Omega. \label{fixdados}
\end{gather}

First, we multiply equation \eqref{fixpfe} successively by $\phi$,
$\phi_t $ and $ -\Delta \phi$, and integrate over $\Omega $. After
integration by parts, using H\"older and Young inequalities we
obtain
\begin{gather}
\frac{1}{2} \frac{d}{dt} \int_{\Omega} | \phi |^2 dx   +
\int_{\Omega} \left( \epsilon^2 | \nabla \phi |^2  +  |\phi|^4
\right) dx   \leq  C_1 + C_2 \int_{\Omega} ( | \theta |^2  + |\phi
|^2) dx, \label{w}
\\
 \frac{1}{2}\int_{\Omega} | \phi_t |^2 dx   + \frac{d}{dt}
\int_{\Omega} \left( \frac{\epsilon^2}{2} | \nabla \phi |^2 +
\frac{1}{4} |\phi|^4 - \frac{1}{2} | \phi |^2 \right) dx  \leq  C_1
+ C_2 \int_{\Omega}  | \theta |^2    dx, \label{x}
\\
\frac{1}{2} \frac{d}{dt} \int_{\Omega} | \nabla \phi |^2 dx  +
\int_{\Omega} \frac{\epsilon^2}{2} | \Delta \phi |^2  dx \leq C_1 +
C_2 \int_{\Omega} ( | \theta |^2 + |\nabla \phi |^2 ) dx. \label{y}
\end{gather}
Next, by multiplying \eqref{fixte} with $ \theta $, arguments
similar to the previous ones lead to the following estimate
\begin{equation}
\frac{1}{2}\frac{d}{dt} \int_{\Omega}  | \theta |^2 dx + K
\int_{\Omega} | \nabla \theta |^2 dx  \leq \frac{1}{8} \int_{\Omega}
| \phi_t |^2 dx + C_1 \int_{\Omega} (| \theta |^2 + |\phi|^2)dx
\label{z}.
\end{equation}
Now, multiply \eqref{x} by $ \frac{1}{2} $ and add the result to
\eqref{w}, \eqref{y} and \eqref{z} to obtain
\begin{equation}
\begin{aligned}
\frac{d}{dt} \int_{\Omega}
 \Big(\frac{1}{4} | \phi |^2  + \big(
\frac{\epsilon^2}{4} + & \frac{1}{2} \big) | \nabla \phi |^2 +
\frac{1}{8} |\phi|^4 + \frac{1}{2} | \theta |^2 \Big) dx
 \\
 + \int_{\Omega} \Big( \epsilon^2 | \nabla \phi |^2  + &
 |\phi|^4  + \frac{1}{8}  | \phi_t |^2 +
\frac{\epsilon^2}{2} | \Delta \phi |^2 + K | \nabla \theta |^2
 \Big) dx
 \\
 & \leq  C_1 + C_2 \int_{\Omega} \left( | \theta |^2 + |\phi |^2  +
| \nabla \phi |^2 \right) dx. \label{bb}
\end{aligned}
\end{equation}
Integrating with respect $t$ and using Gronwall's lemma we find
\[
\| \phi \|_{L^{\infty}(0,T;H^1(\Omega))} + \| \theta
\|_{L^{\infty}(0,T;L^2(\Omega))}  \leq C_1 ,
\]
where $C_1$ is independent of $\lambda$.
Therefore, all fixed points of
$\mathcal{T}_{\lambda}$ in $B$ are bounded independently of $\lambda \in [0,1]$.


Finally, observe that the equation $x - \mathcal{T}_0(x) = 0$ is
equivalent to say that problem \eqref{auxpfe}-\eqref{auxdados} for
$\lambda = 0$ has a unique solution. This  is concluded reasoning
exactly as in the beginning of this proof, when we proved that
$\mathcal{T}_\lambda$ was well defined.

Therefore, we can apply Leray-Schauder's fixed point theorem, and so
there is at least one fixed point $(\phi, \theta) \in B \cap
W^{2,1}_2(Q) \times W^{2,1}_2(Q)  $ of the operator $\mathcal{T}_1$,
i.e., $(\phi, \theta ) = \mathcal{T}_1(\phi,\theta)$. This
corresponds to a solution of problem
\eqref{regularpfe}-\eqref{regulardados}.

To prove estimate \eqref{regularest}, observe that from \eqref{bb} it
follows
\begin{equation} \label{cc}
\|\phi\|_{W^{2,1}_2(Q)} + \|\theta\|_{L^2(0,T;H^1(\Omega))\cap
L^\infty(0,T;L^2(\Omega))}
 \leq C \big( \|\phi_0\|_{H^1(\Omega)}
+ \|\theta_0\|_{L^2(\Omega)} + 1 \big).
\end{equation}
To obtain an estimate for $ \|\theta\|_{W^{2,1}_2(Q)}$, we apply
$L^p$-theory of parabolic equations
\[ \|\theta \|_{W^{2,1}_2(Q)} \leq C \bigl (
\|\theta_0\|_{H^1(\Omega)} + \|\phi_t \|_{L^2(Q)} +
\|\phi\|_{L^2(Q)} + 1 \bigr).\]
Using \eqref{cc} we deduce the desired estimate. The proof of
Proposition \ref{regularizado} is thus complete.
\end{proof}


\section{Existence and uniqueness}

In this section, we prove the well-posedness of problem
\eqref{originalpfe}-\eqref{dados}. We begin with the following
existence result.

\begin{theorem} \label{existencia}
Let be given functions satisfying: $\phi_0,\, \theta_0 \in H^{1+
\gamma}(\Omega)$ with $1/2 < \gamma \leq 1$, the compatibility
condition  $\displaystyle \frac{\partial \phi_0}{\partial n} =
\frac{\partial \theta_0}{\partial n} =0$ a.e. on $\partial \Omega $
and  such that $-1 \leq \phi_0 \leq 1 $ a.e. in $ \Omega$. Then
there exists
 $ (\phi, \theta) \in W^{2,1}_2(Q)\times  W^{2,1}_2(Q) $
solution to problem \eqref{originalpfe}-\eqref{dados} which
satisfies
\[
-1 \leq \phi \leq 1 \quad \mbox{for all } t \in [0,T] \mbox{ and a.e. in }
\Omega.
\]
In addition to that the following estimate
\begin{equation} \label{originalest}
\|\phi\|_{W^{2,1}_2(Q)} + \|\theta\|_{W^{2,1}_2(Q)} \leq C
\bigl(\|\phi_0\|_{H^1(\Omega)} + \|\theta_0\|_{H^1(\Omega)} +
1\bigr)
\end{equation}
holds with  $C$ depending on $ \Omega, \, T $ and the physical
parameters.
\end{theorem}

\begin{proof} Observe that it suffices to show that a solution
 $(\phi,\theta) \in
W^{2,1}_2(Q)\times W^{2,1}_2(Q) $  to  auxiliary problem
\eqref{regularpfe}-\eqref{regulardados} with $-1 \leq \phi_0 \leq 1
$ a.e. in $ \Omega$ satisfies $ -1 \leq \phi \leq 1 $. In fact, if $
-1 \leq \phi \leq 1 $ by definition of the operator $ \Pi$ we have
that $ \Pi(\phi) = \phi $ and, subsequently, $ (\phi,\theta) $ will
be a solution of the original problem
\eqref{originalpfe}-\eqref{dados}.

First, we prove that if $ \phi_0 \leq 1 $ a.e. in $ \Omega $ then $
\phi(t) \leq 1 $  for all $ t \in [0,T] $ and a.e. in $ \Omega$. Let
us consider the positive part of $ (\phi -1) $ namely $ (\phi -1)^+
= \max (\phi-1,0)$. According to \cite{Gilbarg}, we have that $
\nabla (\phi-1)^+ = \nabla \phi $ if $ \phi -1 \geq 0 $ and $ \nabla
(\phi-1)^+  = 0 $ otherwise. Similarly, we have $ (\phi -1)^+_t =
\phi_t $ if $ \phi -1 \geq 0 $ and $ (\phi-1)^+_t  = 0 $ otherwise.

 Multiplying equation \eqref{regularpfe} by $(\phi -1)^+ $
and integrating over $ \Omega \times (0,t) $, for any $ 0 \leq t
\leq T$, we obtain
\begin{align*}
 &\| (\phi-1)^+
(t)\|_{L^2(\Omega)}^2 + \epsilon^2 \int_0^t \|\nabla (\phi-1)^+
\|^2_{L^2(\Omega)} ds \\
& = \| (\phi_0-1)^+ \|_{L^2(\Omega)}^2 +
\int_0^t \int_\Omega \Bigl( \phi - \phi^3 + \dfrac{(\theta_M
-\theta)}{\delta}(1-\Pi(\phi)^2)^2 \Bigr)(\phi-1)^+ \,dx\,ds.
\end{align*}
Since  $ \phi_0 \leq 1 $ one has that $ \| (\phi_0-1)^+
\|_{L^2(\Omega)} = 0$. Moreover, if $ \phi < 1 $ the last integral
vanishes. Now, observe that if  $ \phi \geq 1 $ we have that
$ (\phi - \phi^3)(\phi-1)^+ = \phi (1-\phi^2) (\phi-1)^+ \leq 0 $ and
$\Pi(\phi) =1 $. Thus $ (1-\Pi(\phi)^2)^2 = 0$ and so we can conclude
that
\[
\| (\phi-1)^+ (t)\|_{L^2(\Omega)}^2  \leq 0, \quad \mbox{for all }
 0 \leq t \leq T.
\]
 Therefore, $ (\phi-1)^+ (t) = 0 $ for all $ 0 \leq t \leq T $
and a.e. in $ \Omega$, which implies that $ \phi(t) \leq 1 $ for all
$ 0 \leq t \leq T $ and a.e. in $ \Omega$.

Next, we prove that if $ \phi_0 \geq -1 $ a.e. in $ \Omega $ then $
\phi(t) \geq -1 $  for all $ t \in [0,T] $ and a.e. in $ \Omega$.
For this  we consider the negative part of $ (\phi +1) $ namely $
(\phi +1)^- = \max (-(\phi+1),0). $ By multiplying equation
\eqref{regularpfe} by $ -(\phi +1)^-$ we obtain
\begin{align*}
& \| (\phi+1)^-
(t)\|_{L^2(\Omega)}^2 + \epsilon^2 \int_0^t \|\nabla (\phi+1)^-
\|^2_{L^2(\Omega)} ds  \\
&= \| (\phi_0+1)^- \|_{L^2(\Omega)}^2 +
\int_0^t \int_\Omega \bigl( \phi - \phi^3 + \dfrac{(\theta_M
-\theta)}{\delta}(1-\Pi(\phi)^2)^2 \bigr)\bigl(-(\phi+1)^-\bigr)
\,dx\,ds.
\end{align*}
Similarly as before, since $ \phi_0 \geq -1 $ we have that
$ \|(\phi_0+1)^- \|_{L^2(\Omega)} = 0$.
 Moreover, if $ \phi \geq - 1 $
the last integral vanishes. Now, observe that if  $ \phi < - 1 $ we
have that $ (\phi - \phi^3)\bigl(-(\phi+1)^-\bigr) = \phi
(1-\phi)(1+\phi)\bigl( -(\phi+1)^-\bigr) \leq 0 $ and
$ \Pi(\phi) =-1 $. Thus $ (1-\Pi(\phi)^2)^2 = 0$ and we deduce
\[
\| (\phi+1)^- (t)\|_{L^2(\Omega)}^2  \leq 0, \quad \mbox{for all }
0 \leq t \leq T.
\]
Therefore, $ (\phi+1)^- (t) = 0 $ for all $ 0 \leq t \leq T $
and a.e. in $ \Omega$, which implies that $ \phi(t) \geq -1 $ for
all $ 0 \leq t \leq T $ and a.e. in $ \Omega$. The proof is then
complete.
\end{proof}

We will prove stability of the solutions which will give us
uniqueness at the same time. We will denote by $C$ a positive
constant that  may change from one relation to another.

\begin{theorem} \label{stability}
Let be given functions satisfying: $\phi_0^i,\, \theta_0^i \in H^{1+
\gamma}(\Omega)$ with $1/2 < \gamma \leq 1$, $ \dfrac{\partial
\phi_0^i}{\partial n} = \dfrac{\partial \theta_0^i}{\partial n} =0$
a.e. on $\partial \Omega $ and  such that $-1 \leq \phi_0^i \leq 1 $
a.e. in $ \Omega, \, i = 1,2$. Let
 $ (\phi_i, \theta_i) $ be the corresponding solutions to
problem \eqref{originalpfe}-\eqref{dados}.
Then the following stability estimate holds
\[
\|\phi_1 - \phi_2\|_{W^{2,1}_2(Q)} + \|\theta_1 -
\theta_2\|_{W^{2,1}_2(Q)} \leq C \bigl(\|\phi_0^1 -
\phi_0^2\|_{H^1(\Omega)} + \|\theta_0^1- \theta_0^2\|_{H^1(\Omega)}
\bigr),
\]
where $C$ depends on $ \|\phi_i\|_{W^{2,1}_2(Q)}$ and $ \|
\theta_i\|_{W^{2,1}_2(Q)}$.
\end{theorem}

\begin{proof} We observe that  $\phi= \phi_1 - \phi_2 $ and
$\theta = \theta_1 - \theta_2 $ verify the following problem
\begin{gather}
\begin{aligned}
 \phi_t  -  \epsilon^2 \Delta \phi   =  & \phi (1- (\phi_1^2 + \phi_1
\phi_2 + \phi_2^2) ) \\
&  + \dfrac{(\theta_M-
 \theta_1)}{\delta}(1-\phi_1^2)^2  -  \dfrac{(\theta_M-
 \theta_2)}{\delta}(1-\phi_2^2)^2  \quad \mbox{in } Q,
\end{aligned}\label{estapfe}
\\
 \theta_t  - K \Delta \theta + b \theta  =   \frac{\delta}{2} \phi_t + \alpha
 \phi \quad \mbox{in } Q, \label{estate}
\\
\frac{\partial \phi}{\partial n} = 0 ,\quad  \frac{\partial \theta}
{\partial n} = 0
 \quad \mbox{on } \partial \Omega \times (0,T),
\\
\phi(0) = \phi_0^1 - \phi_0^2   =  \phi_0 ,\quad  \theta(0) =
\theta_0^1- \theta_0^2 = \theta_0 \quad \mbox{in } \Omega.
\label{estadados}
\end{gather}
Now, using the identity $ (1-\phi_1^2)^2 - (1-\phi_2^2)^2 = \phi
(\phi_1+\phi_2) (\phi_1^2 + \phi_2^2 -2)  $  equation
\eqref{estapfe} can be written as
\begin{align*} \phi_t
- \epsilon^2 \Delta \phi
&=  \phi \bigl(1- (\phi_1^2 + \phi_1 \phi_2 + \phi_2^2) \bigr)
  + \dfrac{\theta_M}{\delta}\phi
(\phi_1+\phi_2) (\phi_1^2 + \phi_2^2 -2)   \\
&\quad +  \dfrac{1}{\delta}\theta_1 \phi (\phi_1+\phi_2) (\phi_1^2 +
\phi_2^2 -2)
   + \dfrac{1}{\delta} \theta (1-\phi_2^2)^2.
\end{align*}
Since $ |\phi_i| \leq 1, $ from $ L^p$-theory of parabolic equations
we have
\[
\|\phi\|_{W^{2,1}_2(Q)} \leq C \bigl( \|\phi_0 \|_{H^1(\Omega)} +
\|\phi \|_{L^2(Q)} + \|\theta \|_{L^2(Q)} + \|\theta_1 \phi
\|_{L^2(Q)} \bigr)
\]
and
\begin{align*}
\|\theta\|_{W^{2,1}_2(Q)}
& \leq C \bigl( \|\theta_0
\|_{H^1(\Omega)} + \|\phi_t \|_{L^2(Q)} + \|\phi \|_{L^2(Q)} \bigr)
\\
& \leq C \bigl( \|\theta_0
\|_{H^1(\Omega)} + \|\phi_0 \|_{H^1(\Omega)} + \|\phi \|_{L^2(Q)} +
\|\theta \|_{L^2(Q)} + \|\theta_1 \phi \|_{L^2(Q)} \bigr) .
\end{align*}
The $L^2$-norm of $ \theta_1 \phi $ can be bounded by
using H\"older inequality and the Sobolev embedding
\begin{align*}
\|\theta_1 \phi \|_{L^2(Q)}
 & \leq \Bigl(\int_0^T \|\theta_1\|_{L^4(\Omega)}^2
  \|\phi\|_{L^4(\Omega)}^2dt\Bigr)^{1/2}\\
& \leq C \|\theta_1\|_{L^\infty(0,T;H^1(\Omega))}
\|\phi\|_{L^2(0,T;H^1(\Omega))}.
\end{align*}
Thus, we  conclude that
\begin{equation} \label{ambas}
\|\phi\|_{W^{2,1}_2(Q)} + \|\theta\|_{W^{2,1}_2(Q)}
\leq C \bigl( \|\phi_0 \|_{H^1(\Omega)} + \|\theta_0
\|_{H^1(\Omega)}  + \|\theta \|_{L^2(Q)} +
\|\phi\|_{L^2(0,T;H^1(\Omega))} \bigr).
\end{equation}

To obtain estimates for $ \phi $ and $ \theta$  we return to
equations \eqref{estapfe}-\eqref{estate} and use standard
techniques. We first deduce that
\[
 \frac{1}{2} \frac{d}{dt}\|\phi\|_{L^2(\Omega)}^2 + \epsilon^2\|\nabla \phi
\|_{L^2(\Omega)}^2 \leq C \bigl(\|\phi \|_{L^2(\Omega)}^2 + \|\theta
\|_{L^2(\Omega)}^2 + \int_\Omega | \theta_1|\, |\phi|^2 dx\bigr),
\]
where we used that $ |\phi_i | \leq 1$.

The last term can be bounded by using H\"older and Young
inequalities
\begin{align*}
 \int_\Omega | \theta_1|\, |\phi|^2 dx
& \leq \|\theta_1\|_{L^4(\Omega)} \|\phi\|_{L^4(\Omega)}
\|\phi\|_{L^2(\Omega)} \\
&\leq C\|\theta_1\|_{L^\infty(0,T;H^1(\Omega))}^2
\|\phi\|_{L^2(\Omega)}^2 + \frac{\epsilon^2}{2}\|\nabla
\phi\|_{L^2(\Omega)}^2.
\end{align*}
By rearranging  terms we arrive at
\[
\frac{d}{dt}\|\phi\|_{L^2(\Omega)}^2 + \epsilon^2\|\nabla \phi
\|_{L^2(\Omega)}^2 \leq C \bigl(\|\phi \|_{L^2(\Omega)}^2 + \|\theta
\|_{L^2(\Omega)}^2 \bigr) .
\]
Next, by multiplying equation \eqref{estate} by $ \theta $, we
obtain, for any $ \eta > 0 $,
\[
\frac{1}{2} \frac{d}{dt} \|\theta\|^2_{L^2(\Omega)} + K \|\nabla
\theta\|^2_{L^2(\Omega)} \leq \eta \|\phi_t \|_{L^2(\Omega)}^2  + C
\bigl(  \|\phi \|_{L^2(\Omega)}^2 + \|\theta \|_{L^2(\Omega)}^2
\bigr).
\]
 By integrating in time we deduce from the above relations
that
\begin{align*}
&\|\phi\|_{L^2(\Omega)}^2 +
\|\theta\|^2_{L^2(\Omega)} + \int_0^t \bigl( \|\nabla \phi
\|_{L^2(\Omega)}^2 + \|\nabla \theta\|^2_{L^2(\Omega)} \bigr) ds \\
&\leq C \bigl( \|\phi_0 \|_{L^2(\Omega)}^2 + \|\theta_0
\|_{L^2(\Omega)}^2 + \int_0^t (\|\phi \|_{L^2(\Omega)}^2 + \|\theta
\|_{L^2(\Omega)}^2)ds \bigr)+ \eta \|\phi_t \|_{L^2(Q)}^2
\end{align*}
Taking $\eta $ small enough and using \eqref{ambas}  yields
\begin{align*}
&\|\phi\|_{L^2(\Omega)}^2 +
\|\theta\|^2_{L^2(\Omega)} + \int_0^t \bigl( \|\nabla \phi
\|_{L^2(\Omega)}^2 + \|\nabla \theta\|^2_{L^2(\Omega)} \bigr) ds \\
&\leq C \bigl( \|\phi_0 \|_{H^1(\Omega)}^2 + \|\theta_0
\|_{H^1(\Omega)}^2 + \int_0^t( \|\phi \|_{L^2(\Omega)}^2 + \|\theta
\|_{L^2(\Omega)}^2 )ds \bigr).
\end{align*}
Gronwall's lemma  implies
\begin{align*}
&\|\phi\|_{L^2(\Omega)}^2 + \|\theta\|^2_{L^2(\Omega)} + \int_0^t \bigl( \|\nabla \phi
\|_{L^2(\Omega)}^2 + \|\nabla \theta\|^2_{L^2(\Omega)} \bigr) ds \\
&\leq C \bigl( \|\phi_0 \|_{H^1(\Omega)}^2 + \|\theta_0
\|_{H^1(\Omega)}^2  \bigr).
\end{align*}
By plugging this in \eqref{ambas} we obtain the desired stability
result.
\end{proof}

\begin{corollary} \label{unicidade}
Let assumptions in theorem \ref{existencia} be fulfilled. Then there exists a unique solution
$ (\phi, \theta) \in W^{2,1}_2(Q) \times W^{2,1}_2(Q)$ to problem
\eqref{originalpfe}-\eqref{dados}.
\end{corollary}


\begin{remark} \label{rmk5} \rm
The results stated in Theorems \ref{existencia} and \ref{stability} still hold,
exactly with the
same proofs, for initial conditions $\phi_0$ and $ \theta_0$ in any
functional space including $H^1(\Omega)$ and for which it makes
sense to require that $ \dfrac{\partial \phi_0}{\partial n} =
\dfrac{\partial \theta_0}{\partial n}= 0$ a.e. on $\partial \Omega$
in order to apply $L^p$-theory of the parabolic linear equations.
Moreover, a weaker version of theorems hold, with a natural weaker
formulation of (\ref{originalpfe})-(\ref{dados}), for initial
conditions $\phi_0$ and $ \theta_0$ just in $H^1(\Omega)$. For the
proof, it is enough to take sequences in $ H^{1+ \gamma}(\Omega)$
with $1/2 < \gamma \leq 1$ satisfying the compatibility condition
and converging to $\phi_0$ and $ \theta_0$ in $H^1(\Omega)$, and
then to consider a sequence of approximate problems with these
initial conditions. Since the sequence of approximate solutions will
satisfy estimate \eqref{originalest}, it will be possible to pass to
the limit and recover a solution of the original problem.
\end{remark}

We will prove a regularity result under the additional assumption
that the initial data are smooth enough by using $L^p$-theory of the
parabolic linear equations together with bootstrapping arguments.


\begin{theorem}
Let $ p \geq 2$. Let be given functions satisfying:
$\phi_0,\, \theta_0 \in W^{2-\frac{2}{p}}_p(\Omega) \cap H^{1+ \gamma}(\Omega)$
with $1/2 <\gamma \leq 1$, $ \dfrac{\partial \phi_0}{\partial n} =
\dfrac{\partial \theta_0}{\partial n} =0$ a.e. on $\partial \Omega $
and  such that $-1 \leq \phi_0 \leq 1 $ a.e. in $ \Omega$. Then the
unique solution to problem \eqref{originalpfe}-\eqref{dados}
satisfies
 \[
(\phi, \theta) \in W^{2,1}_p(Q)\times  W^{2,1}_p(Q).
 \]
\end{theorem}

\begin{proof} According to theorem \ref{existencia} and corollary
\ref{unicidade} there exists a unique solution $ (\phi,\theta) \in
W^{2,1}_2(Q) \times W^{2,1}_2(Q)$ to problem
\eqref{originalpfe}-\eqref{dados}. Since $ |\phi| \leq 1 $ and $
W^{2,1}_2(Q) \hookrightarrow L^{10}(Q)$ from $L^p$-theory of
parabolic equations applied to the phase-field equation  we have
that $ \phi \in W^{2,1}_{10}(Q)$ and, subsequently,  from the
temperature equation we conclude $ \theta \in W^{2,1}_{10}(Q)$. Now,
since $ W^{2,1}_{10}(Q) \hookrightarrow L^{\infty}(Q)$ by applying
again $L^p$-theory of parabolic equations we conclude that $ \phi
\in W^{2,1}_p(Q) $ for any $ p \geq 2$ and consequently $ \theta \in
W^{2,1}_p(Q) $ for any $ p \geq 2$.
\end{proof}

\subsection*{Acknowledgements.}
 The author would like to thank  to the
anonymous referee for his/her valuable suggestions and comments.


\begin{thebibliography}{99}

\bibitem{Blyuss}Blyuss KB, Ashwin P, Wright CD, Bassom
AP. Front propagation in a phase field model with phase-dependent
heat absorption. \emph{Physica D} \textbf{215} (2006), 127-136.


\bibitem{Boldrini} Boldrini JL, Planas G. Weak solutions of a
phase-field model for phase change of an alloy with thermal
properties. \emph{Mathematical Methods in the Applied Sciences}
\textbf{25} (2002), no. 14, 1177-1193.

\bibitem{Caginalp}Caginalp G.
An analysis of a phase field model of a free boundary. \emph{Archive
for Rational Mechanics and Analysis} \textbf{92} (1986), 205-245.

\bibitem{ColliHoffmann} Colli H, Hoffmann, K-H. A nonlinear evolution
problem describing multi-component phase changes with dissipation.
\emph{Numerical Functional Analysis and Optimization} \textbf{14}
(1993), no. 3-4, 275--297.


\bibitem{Colli} Colli P, Kenmochi N, Kubo M. A phase-field model with temperature dependent
constraint. \emph{Journal of Mathematical Analysis and Applications}
\textbf{256} (2001), no. 2, 668-685.

\bibitem{Friedman}Friedman A. \emph{Partial Differential Equation of Parabolic
Type}. Prentice-Hall, 1964.

\bibitem{Gilbarg} Gilbarg D, Trudinger NS. \emph{Elliptic
Partial Differential Equations of Second Order}. Springer, Berlin,
1983.

\bibitem{Hoffman}Hoffmann K-H, Jiang L.
Optimal control of a phase field model for solidification. \emph{
Numerical Functional Analysis and Optimization} \textbf{13} (1992),
11-27.

\bibitem{Lady}Ladyzenskaja OA, Solonnikov VA,
Ural'ceva NN. \emph{Linear and Quasilinear Equations of Parabolic
Type}. American Mathematical Society, Providence, 1968.

\bibitem{Lions} Lions J-L. \emph{Contr\^ole des syst\`emes distribu\'es singuliers
[Control of singular distributed systems]}. M\'ethodes
Math\'ematiques de l'Informatique [Mathematical Methods of
Information Science], 13. Gauthier-Villars, Montrouge, 1983.

\bibitem{Moro}Moro\c{s}anu C, Motreanu D. A generalized
phase-field system. \emph{Journal of Mathematical Analysis and
Applications} \textbf{237} (1999), 515-540.

\bibitem{Rappaz}Rappaz J, Scheid JF. Existence of solutions to a phase-field model for the isothermal
solidification process of a binary alloy. \emph{Mathematical Methods
in the Applied Sciences} \textbf{23} (2000), 491-512.

\bibitem{Simon}Simon J. Compact sets in the space $ L^p(0,T,B)$. \emph{ Annali di Matematica Pura ed
Applicata} \textbf{146} (1987), 65-96.

\bibitem{Stefanelli} Stefanelli U. Error control of a nonlinear evolution problem
related to phase transitions. \emph{Numerical Functional Analysis
and Optimization} \textbf{20} (1999), no. 5-6, 585--608.

\end{thebibliography}





\end{document}