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

\AtBeginDocument{{\noindent\small
\emph{Electronic Journal of Differential Equations},
Vol. 2008(2008), No. 165, pp. 1--6.\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 2008 Texas State University - San Marcos.}
\vspace{9mm}}

\begin{document}
\title[\hfilneg EJDE-2008/165\hfil Multiple solutions]
{Multiple solutions for quasilinear elliptic problems with
 nonlinear boundary conditions}

\author[N. T. Chung\hfil EJDE-2008/165\hfilneg]
{Nguyen Thanh Chung}  

\address{Department of Mathematics and Informatics\\
Quang Binh University\\
312 Ly Thuong Kiet, Dong Hoi, Quang Binh, Vietnam}
\email{ntchung82@yahoo.com}

\thanks{Submitted October 20, 2008. Published December 23, 2008.}
\subjclass[2000]{35J65, 35J20}
\keywords{Multiple solutions; quasilinear elliptic problems; \hfill\break\indent
nonlinear boundary conditions}

\begin{abstract}
 Using a recent result by Bonanno \cite{2}, we obtain a
 multiplicity result for the quasilinear elliptic problem
 \begin{gather*}
 - \Delta_p u + |u|^{p-2}u  = \lambda f(u) \quad \text{in } \Omega, \\
 |\nabla u|^{p-2} \frac{\partial u}{\partial \nu}
 = \mu g(u) \quad \text{on } \partial\Omega,
 \end{gather*}
 where $\Omega$ is a bounded domain in $\mathbb R^N$, $N \geq  3$
 with smooth boundary $\partial\Omega$, $\frac{\partial}{\partial\nu}$
 is the outer unit normal derivative,
 the functions $f, g$ are $(p-1)$-sublinear at infinity
 ($1 <p < N$), $\lambda$ and $\mu$ are positive parameters.
\end{abstract}

\maketitle
\numberwithin{equation}{section}
\newtheorem{theorem}{Theorem}[section]
\newtheorem{lemma}[theorem]{Lemma}
\newtheorem{remark}[theorem]{Remark}
\newtheorem{definition}[theorem]{Definition}

\section{Introduction and Preliminaries}

Let $\Omega$ be a bounded domain in $\mathbb R^N$, $N \geq  3$
with smooth boundary $\partial\Omega$ and a constant
$p$ with $1 < p < N$. In this paper, we consider the
quasilinear elliptic problems
\begin{equation}\label{e1.1}
\begin{gathered}
- \Delta_p u + |u|^{p-2}u  = \lambda f(u) \quad \text{in } \Omega, \\
|\nabla u|^{p-2} \frac{\partial u}{\partial \nu}  = \mu g(u) \quad\text{on }
\partial\Omega.
\end{gathered}
\end{equation}
Such problems were studied in many works, for example  \cite{1,3,4,5,6}.
In \cite{3},  Bonder
studied the problem in the case: $f \equiv 0$ and $g$ is a sign-changing
Carath\'{e}odory function. Then, using the
variational techniques in \cite{8} the author
obtained at least two solutions in the space
 $W^{1,p}(\Omega)$ provided that $\mu$ is large enough. In \cite{4},
 the author considered a more general situation,
where the functions $f,g$ are involved,
but not the parameters $\lambda$ and $\mu$. Using the Lusternik -
Schnirelman method for non-compact manifolds, the author showed the
existence of at least three solutions, and the sign of the
solutions are also well-defined. We also find that the
lower and upper solutions and variational methods
were combined with together in \cite{1} to obtain
multiplicity results for the problems of (\ref{e1.1}) type.
Finally, in the papers \cite{5}, \cite{6} and \cite{12},
existence results of infinitely many solutions
were investigated and the corresponding Neumann problems involving the
$p(x)$-Laplacian operator were also studied in \cite{7} and \cite{11}. In the present paper,
we are interested in the case: the functions $f, g$ are
$(p-1)$-sublinear at infinity. Hence, our main ingredient is a recent critical
point result due to G. Bonanno \cite{2}. Using this interesting
result we show that problem (\ref{e1.1})
has at least two nontrivial solutions provided that $\lambda$ and $\mu$
are suitable. In order to state our main result
 we introduce some hypotheses.

We assume that the functions $f$ and $g : \mathbb{R} \to \mathbb{R}$
satisfy the following conditions:
\begin{enumerate}
\item[(H1)] There exist constants $M_1, M_2 > 0$ such that
for all $t \in \mathbb{R}^N$,
$$
|f(t)| \leq  M_1(1+|t|^{p-1}), \quad |g(t)| \leq  M_2|t|^{p-1}\,;
$$

\item[(H2)] $f$ is superlinear at zero; i.e.,
$$
\lim_{t\to 0}\frac{f(t)}{|t|^{p-1}} = 0;
$$
\item[(H3)] if we set $F(t) = \int_0^t f(t)dt$ and $G(t) = \int_0^t g(t)dt$,
 then there exists $t_0 \in \mathbb{R}$ such that
$$
F(t_0) = \int_0^{t_0}f(t)dt > 0 \quad\text{or}\quad
G(t_0) = \int_0^{t_0}g(t)dt > 0.
$$
\end{enumerate}

Let $W^{1,p}(\Omega)$ be the usual Sobolev space with respect to the norm
$$
\|u\|_{1,p}^p = \int_\Omega (|\nabla u|^p + |u|^p) dx
$$
and $W^{1,p}_0(\Omega)$ the closure of $C^\infty_0(\Omega)$ in
$W^{1,p}(\Omega)$.
For any $1 < p < N$ and $1 \leq  q \leq  p^\star = \frac{Np}{N-p}$,
we denote by
$S_{q,\Omega}$ the best constant in the embedding $W^{1,p}(\Omega)
\hookrightarrow L^q(\Omega)$ and for all
$1 \leq  q \leq  p_\star = \frac{(N-1)p}{N-p}$,
we also denote by $S_{q,\partial\Omega}$ the best constant in the embedding
 $W^{1,p}(\Omega) \hookrightarrow L^q(\partial\Omega)$, i.e.
$$
S_{q,\partial\Omega} = \inf_{u \in W^{1,p}(\Omega)\backslash W^{1,p}_0(\Omega)}
\frac{\int_\Omega (|\nabla u|^p + |u|^p) dx}{\big(\int_{\partial\Omega}
|u|^qd\sigma\big)^{p/q}}.
$$
Moreover, if $1 \leq  q < p^\star$, then the embedding $W^{1,p}(\Omega)
\hookrightarrow L^q(\Omega)$ is compact and if
$1 \leq  q < p_\star$, then the embedding $W^{1,p}(\Omega)
\hookrightarrow L^q(\partial\Omega)$ is compact. As a consequence, we
have the existence of extremals, i.e. functions where the
infimum is attained (see \cite{3, 6}).

\begin{definition}\label{def1.1} \rm
We say that $u \in W^{1,p}(\Omega)$ is a weak solution of problem
(\ref{e1.1}) if and only if
$$
\int_\Omega (|\nabla u|^{p-2}\nabla u\nabla\varphi + |u|^{p-2}u\varphi)dx -
\lambda \int_\Omega f(u)\varphi dx - \mu \int_{\partial\Omega} g(u) \varphi d\sigma = 0
$$
for all $\varphi \in W^{1,p}(\Omega)$.
\end{definition}

\begin{theorem}\label{thm1.2}
Assuming hypotheses {\rm (H1)--(H3)} are fulfilled then there exist
an open interval $\Lambda_\mu$ and a constant $\delta_\mu >0$ such that
for all $\lambda \in \Lambda_\mu$, problem (\ref{e1.1}) has at least
two weak solutions in $W^{1,p}(\Omega)$ whose $\|\cdot\|_{1,p}$-norms
are less than $\delta_\mu$.
\end{theorem}

We emphasize that the condition (H3) cannot be omitted. Indeed,
if for instance $f\equiv 0$ and $g\equiv 0$, then (H1) and (H2)
clearly hold, but problem (\ref{e1.1}) has only the trivial solution.
Theorem \ref{thm1.2} will be proved by using a recent result on
the existence of at least
 three critical points by Bonanno \cite{2} which is
actually a refinement of a general principle
of  Ricceri (see \cite{9, 10}). For the reader's convenience,
we describe it as follows.

\begin{lemma}[see {\cite[Theorem 2.1]{2}}] \label{lem1.3}
Let $(X, \|\cdot\|)$ be a separable and reflexive real Banach space,
 $\mathcal A, \mathcal F : X \to \mathbb{R}$ be two continuously
G\^{a}teaux differentiable functionals.
Assume that there exists $x_0 \in X$ such that
$\mathcal A(x_0) = \mathcal F(x_0) = 0$,
$\mathcal A(x) \geq  0$ for all $x \in X$
and there exist $x_1 \in X$, $\rho > 0$ such that
\begin{itemize}
\item[(i)] $\rho < \mathcal A(x_1)$,
\item[(ii)] $\sup_{\{\mathcal A(x)< \rho\}} \mathcal F(x)
< \rho \frac{\mathcal F(x_1)}{\mathcal A(x_1)}$.
\end{itemize}
Further, put
$$
\overline{a} = \frac{\xi \rho}{\rho \frac{\mathcal F(x_1)}{\mathcal A(x_1)}
 - \sup_{\{\mathcal A(x) < \rho\}}\mathcal F(x)}, \quad \text{with } \xi > 1,
$$
and assume that the functional $\mathcal A - \lambda \mathcal F$
 is sequentially weakly lower semicontinuous, satisfies the
Palais-Smale condition and
\begin{itemize}
\item[$(iii)$] $\lim_{\|x\| \to \infty}[\mathcal A(x) -
\lambda \mathcal F(x)] = +\infty$ for every $\lambda \in [0, \overline{a}]$.
\end{itemize}
Then, there exist an open interval $\Lambda \subset [0,\overline{a}]$
 and a positive real number $\delta$ such that each $\lambda \in \Lambda$, the
equation
$$
D\mathcal A(u) - \lambda D\mathcal F(u) = 0
$$
has at least three solutions in $X$ whose $\|\cdot\|$-norms are less
than $\delta$.
\end{lemma}

\section{Multiple solutions}

Throughout this section, we suppose that all
assumptions of Theorem \ref{thm1.2} are satisfied.
For  $\lambda$ and $\mu \in \mathbb{R}$, we define the functional
$\Phi_{\mu,\lambda} : W^{1,p}(\Omega) \to \mathbb{R}$ by
$$
\Phi_{\mu,\lambda}(u) = \mathcal I_\mu(u) -
\lambda \mathcal J (u) \text{ for all } u \in W^{1,p}_0(\Omega),
$$
where
\begin{equation}\label{e2.1}
\mathcal I_\mu(u) = \int_\Omega (|\nabla u|^p + |u|^p)dx
- \mu \int_{\partial\Omega} G(u) d\sigma,
\quad \mathcal J (u) = \int_\Omega F(u) dx
\end{equation}
with
$F(t) = \int_0^t f(t)dt$ and $G(t) = \int_0^t g(t)dt$.

A simple computation implies that the functional $\Phi_{\mu,\lambda}$ is
 of $C^1$-class and hence weak solutions of (\ref{e1.1}) correspond to the critical
points of $\Phi_{\mu,\lambda}$. To prove Theorem \ref{thm1.2}, we
shall apply Lemma \ref{lem1.3} by choosing $X = W^{1,p}(\Omega)$ as
well as $\mathcal A = \mathcal I_\mu$ and $\mathcal F = \mathcal J$
as in (\ref{e2.1}).
Now, we shall check all assumptions of Lemma \ref{lem1.3}.
For each $\mu \in [0, \frac{pS_{p,\partial\Omega}}{M_2})$
we have $\mathcal I_\mu (u) \geq  0$
for all $u \in W^{1, p}(\Omega)$ and
$\mathcal I_\mu(0) = \mathcal J(0) = 0$ since the assumption
(H1) holds. Moreover, by the compact embeddings
$W^{1,p}(\Omega) \hookrightarrow L^p(\Omega)$ and
 $W^{1,p}(\Omega) \hookrightarrow L^p(\partial\Omega)$,
a simple computation helps us
to conclude the following lemma.

\begin{lemma}\label{lem2.1}
For every $\mu \in [0, \frac{pS_{p,\partial\Omega}}{M_2})$ and all
$\lambda \in \mathbb{R}$, the functional $\Phi_{\mu,\lambda}$ is sequentially
weakly lower semicontinuous on $W^{1,p}(\Omega)$.
\end{lemma}

\begin{lemma}\label{lem2.2}
There exist two positive constants $\overline{\mu}$ and $\overline{\lambda}$
such that for all $\mu \in [0, \overline{\mu})$ and all
$\lambda \in [0, \overline{\lambda})$,
the functional $\Phi_{\lambda, \mu}$ is coercive and satisfies the
Palais-Smale condition in $W^{1,p}(\Omega)$.
\end{lemma}

\begin{proof}
By (H1), we have
\begin{align}\label{e2.2}
\Phi_{\mu, \lambda} (u) & = \int_\Omega (|\nabla u|^p + |u|^p)dx -
 \lambda \int_\Omega F(u) dx - \mu\int_{\partial\Omega} G(u) d\sigma\notag\\
& \geq  \|u\|^p_{1,p} - \lambda M_1\int_\Omega (|u|+\frac{|u|^p}{p}) dx -
\mu \frac{M_2}{p}\int_{\partial\Omega}|u|^pd\sigma\notag\\
& \geq  \|u\|^p_{1,p}\Big(1 - \lambda\frac{M_1}{pS_{p, \Omega}} -
\mu \frac{M_2}{pS_{p, \partial\Omega}}\Big) -
\lambda \frac{M_1}{S_{1,\Omega}}\|u\|_{1,p}.
\end{align}
Since relation (\ref{e2.2}) holds, by choosing
$$
\overline{\mu} = \overline{\lambda} = \min\big\{\frac{pS_{p, \Omega}}{2M_1},
 \frac{pS_{p, \partial\Omega}}{2M_2}\big\},
$$
where $M_1$, $M_2$ are given in (H1), we conclude that for all
$\lambda \in [0, \overline{\lambda})$ and all $\mu \in [0, \overline{\mu})$,
the functional $\Phi_{\mu,\lambda}$ is coercive.

Now, let $\{u_m\}$ be a Palais-Smale sequence for the functional
$\Phi_{\mu, \lambda}$ in $W^{1,p}(\Omega)$; i.e.,
\begin{equation}\label{e2.3}
|\Phi_{\mu,\lambda}(u_m)| \leq  \overline{c},\quad
D\Phi_{\mu,\lambda}(u_m) \to 0 \text{ in } W^{-1,p}(\Omega),
\end{equation}
where $W^{-1,p}(\Omega)$ is the dual space of $W^{1,p}(\Omega)$.
Since $\Phi_{\mu,\lambda}$ is coercive, the sequence
$\{u_m\}$ is bounded in $W^{1,p}(\Omega)$. Therefore, there exists
a subsequence of $\{u_m\}$, denoted by $\{u_m\}$ such that
$\{u_m\}$ converges weakly to some $u \in W^{1,p}(\Omega)$ and hence
converges strongly to $u$ in $L^p(\Omega)$ and in $L^p(\partial\Omega)$.
We shall prove that $\{u_m\}$ converges strongly to $u$ in $W^{1,p}(\Omega)$.
Indeed, we have
\begin{align*}
\|u_m -u\|^p_{1,p}
& \leq  \int_\Omega (|\nabla u_m|^{p-2}\nabla u_m-
|\nabla u|^{p-2}\nabla u)(\nabla u_m - \nabla u) dx\\
& \quad + \int_\Omega (|u_m|^{p-2}u_m - |u|^{p-2}u)(u_m-u)dx\\
& = [D\Phi_{\mu,\lambda}(u_m)-D\Phi_{\mu,\lambda}(u)](u_m-u)
+ \lambda \int_\Omega[f(u_m)-f(u)](u_m-u)dx \\
& \quad +\mu \int_{\partial\Omega}[g(u_m)-g(u)](u_m-u)dx.
\end{align*}
On the other hand, the compact embeddings and (H1) imply
\begin{align*}
&|\int_\Omega [f(u_m)-f(u)](u_m-u)dx| \\
& \leq  \int_\Omega |f(u_m)-f(u)||u_m-u|dx \\
& \leq  M_1 \int_\Omega (2 + |u_m|^{p-1}+|u|^{p-1})|u_m-u|dx \\
& \leq  M_1(2 \mathop{\rm meas}(\Omega)^{\frac{p-1}{p}} +\|u_m\|^{p-1}_{L^p(\Omega)}+
\|u\|^{p-1}_{L^p(\Omega)})\|u_m-u\|^{p}_{L^p(\Omega)}
\end{align*}
which approaches $0$ as $m \to \infty$. Similarly, we obtain
\begin{align*}
|\int_{\partial\Omega} [g(u_m)-g(u)](u_m-u)dx|
& \leq  \int_{\partial\Omega} |g(u_m)-g(u)||u_m-u|dx \\
& \leq  M_2 \int_{\partial\Omega} (|u_m|^{p-1}+|u|^{p-1})|u_m-u|dx \\
& \leq  M_2(\|u_m\|^{p-1}_{L^p(\partial\Omega)}+
\|u\|^{p-1}_{L^p(\partial\Omega)})\|u_m-u\|^{p}_{L^p(\partial\Omega)}
\end{align*}
which approaches zero as $m \to \infty$. Hence, by (\ref{e2.3}) we
have $\|u_m - u\|_{1,p} \to 0$
as $m \to \infty$; i.e., the functional $\Phi_{\mu,\lambda}$ satisfies
the Palais-Smale condition.
\end{proof}

\begin{lemma}\label{lem2.3}
For every $\mu \in [0, \overline{\mu})$ with
 $ \overline{\mu}$ as in Lemma \ref{lem2.2}, we have
$$
\lim_{\rho \to 0^+}\frac{\sup\{\mathcal J (u) :
\mathcal I_\mu (u) < \rho\}}{\rho} = 0.
$$
\end{lemma}

\begin{proof}
Let $\lambda \in [0, \overline{\lambda})$ and
$\mu \in [0, \overline{\mu})$ be fixed.
By (H2), for any $\epsilon> 0$,
there exists $\delta = \delta(\epsilon) > 0$ such that
$$
|f(s)| < \epsilon pS_{p, \Omega}\Big(1 - \mu\frac{M_2}{pS_{p,
\partial\Omega}}\Big)|s|^{p-1} \text{ for all } |s| < \delta.
$$
We first fix $q \in (p, p^\star)$. Combining the above inequalities
 with (H1) we deduce that
\begin{equation}\label{e2.4}
|F(s)| \leq  \epsilon S_{p, \Omega}\Big(1 - \mu\frac{M_2}{pS_{p,
 \partial\Omega}}\Big)|s|^{p}+ C_{\delta} |s|^q,
\end{equation}
for all $s \in \mathbb{R}$, where $C_{\delta}$ is a constant depending on $\delta$.
 Now, for every $\rho > 0$, we define the sets
$$
\mathcal{B}^1_\rho =
\{u \in W^{1,p}(\Omega): \mathcal I_\mu (u) <\rho\}
$$
and
$$
\mathcal{B}^2_\rho= \big\{u \in W^{1,p}(\Omega): \Big(1 -
\mu\frac{M_2}{pS_{p, \partial\Omega}}\Big)\|u\|^p_{1,p} <\rho\}.
$$
Then $\mathcal{B}^1_\rho \subset \mathcal{B}^2_\rho$.
 From (\ref{e2.4}) we get
\begin{equation}\label{e2.5}
|\mathcal J(u)| \leq  \epsilon
\Big(1 - \mu\frac{M_2}{pS_{p, \partial\Omega}}\Big)\|u\|^p_{1,p}+
 \frac{C_{\delta}}{S^\frac{q}{p}_{q,\Omega}} \|u\|_{1,p}^q.
\end{equation}
It is clear that $0 \in \mathcal{B}^1_\rho$ and $\mathcal J (0) = 0$. Hence,
$0 \leq  \sup_{u \in \mathcal{B}^1_\rho}\mathcal J (u)$,
using  (\ref{e2.5}) we get
\begin{align}\label{e2.6}
0 \leq  \frac{\sup_{u \in \mathcal{B}^1_\rho}\mathcal J(u)}{\rho} & \leq
\frac{\sup_{u \in \mathcal{B}^2_\rho}\mathcal J(u)}{\rho} \leq  \epsilon +
\frac{C_{\delta}}{S^\frac{q}{p}_{q,\Omega}} \Big(1 - \mu\frac{M_2}{pS_{p,
\partial\Omega}}\Big)^{-\frac{q}{p}} \rho^{\frac{q}{p}-1}.
\end{align}
We complete the proof of the lemma by letting $\rho \to 0^+$,
since $\epsilon > 0$ is arbitrary.
\end{proof}

\begin{proof}[Proof of Theorem \ref{thm1.2} completed]
Let $s_0$ be as in (H3). We choose a constant $r_0 >0$
such that $r_0 < $ dist$ (0, \partial\Omega)$.
For each $\delta \in (0,1)$ we define the function
\begin{equation*}
u_\delta(x) =
\begin{cases}
0, & \text{if } x \in \mathbb{R}^N \backslash B_{r_0}(0) \\
s_0, & \text{if } x \in B_{\delta r_0}(0) \\
\frac{s_0}{r_0(1-\delta)} (r_0 - |x|),
 & \text{if } x \in B_{r_0}(0) \backslash B_{\delta r_0}(0),
\end{cases}
\end{equation*}
where $B_{r_0}(0)$ denotes the open ball with center $0$
and radius $r_0 > 0$. Then, it is clear that
$u_\delta \in W^{1,p}_0(\Omega)$. Moreover, we have
\begin{gather}\label{e2.7}
\|u_\delta\|^p_{1,p} \geq  \frac{|s_0|^p(1-\delta^N)}{(1-\delta)^p}r_0^{N-p}
\omega_N > 0,\\
\label{e2.8}
\mathcal J (u_\delta) \geq  [F(s_0)\delta^{N} -
 \max_{|t| \leq  |s_0|}|F(t)|(1-\delta^{N})]\omega_{N}r_0^{N},
\end{gather}
where $\omega_{N}$ is the volume of the unit ball in $\mathbb{R}^{N}$.
 From (\ref{e2.8}), there is $\delta_0 > 0$ such that
$\|u_{\delta_0}\|_{1,p} > 0$ and $\mathcal J (u_{\delta_0}) > 0$.
Now, by Lemma \ref{lem2.3}, we can choose $\rho_0 \in (0, 1)$
 such that
$$
\rho_0 < \Big(1 - \mu\frac{M_2}{pS_{p, \partial\Omega}}\Big)
\|u_{\delta_0}\|^p_{1,p}
\leq  \mathcal I_\mu (u_{\delta_0})
$$
and satisfies
$$
\frac{\sup\{\mathcal J(u) : \mathcal I_\mu (u) < \rho_0\}}{\rho_0}
< \frac{\mathcal J (u_{\delta_0})}{2 \mathcal I_\mu (u_{\delta_0})}.
$$
To apply Lemma \ref{lem1.3}, we choose $x_1 = u_{\delta_0}$
and $x_0 = 0$. Then, the assumptions (i) and (ii) of
 Lemma \ref{lem1.3} are satisfied. Next, we define
$$
a_\mu = \frac{1+\rho_0}{\frac{\mathcal J (u_{\delta_0})}{ \mathcal I_\mu (u_{\delta_0})}
- \frac{\sup\{\mathcal J (u) : \mathcal I_\mu (u) < \rho_0\}}{\rho_0}} > 0
\quad\text{and}\quad
 \overline{a}_\mu = \min\{a_\mu, \overline{\lambda}\}.
$$
A simple computation implies that $(\bf {iii})$ are verified.
Hence, there exist an open interval
$\Lambda_\mu \subset [0, \overline{a}_\mu]$
and a real positive number $\delta_\mu$ such that for each
$\lambda \in \Lambda_\mu$, the equation
$D\Phi_{\mu,\lambda}(u) =
D\mathcal I_{\mu}(u) - \lambda D \mathcal J(u) = 0$
has at least three solutions in $W^{1,p}(\Omega)$ whose
$\|\cdot\|_{1,p}$-norms are less than $\delta_\mu$. By (H1) and (H2),
one of them may be the trivial one. Thus, (\ref{e1.1}) has at least
two weak solutions in $W^{1,p}(\Omega)$.
The proof is complete.
\end{proof}

\subsection*{Acknowledgments}
The author would like to thank the referees for 
their suggesions and helpful comments on this work.

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\end{document}