\documentclass[reqno]{amsart}
\usepackage{hyperref}

\AtBeginDocument{{\noindent\small
\emph{Electronic Journal of Differential Equations},
Vol. 2013 (2013), No. 141, 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}
\thanks{\copyright 2013 Texas State University - San Marcos.}
\vspace{9mm}}

\begin{document}
\title[\hfilneg EJDE-2013/141\hfil Existence of solutions]
{Existence of solutions to fractional boundary-value
problems with a parameter}

\author[Y. N. Li, H. R. Sun, Q. G. Zhang \hfil EJDE-2013/141\hfilneg]
{Ya-Ning Li, Hong-Rui Sun, Quan-Guo Zhang}  % in alphabetical order

\address{Ya-Ning Li \newline
 School of Mathematics and Statistics, Lanzhou University\\
Lanzhou, Gansu 730000, China}
 \email{liyn08@lzu.edu.cn}

\address{Hong-Rui Sun \newline
School of Mathematics and Statistics, Lanzhou University\\
Lanzhou, Gansu 730000, China}
\email{hrsun@lzu.edu.cn}

\address{Quan-Guo Zhang \newline
School of Mathematics and Statistics, Lanzhou University\\
Lanzhou, Gansu 730000, China}
\email{zhangqg07@lzu.edu.cn}

\thanks{Submitted January 27, 2013. Published June 21, 2013.}
\subjclass[2000]{34A08, 34B09}
\keywords{ Fractional differential equation; eigenvalue;
critical point theory; \hfill\break\indent
 boundary value problem}

\begin{abstract}
 This article concerns the existence of solutions to the   fractional
 boundary-value problem
 \begin{gather*}
 -\frac{d}{dt} \big(\frac{1}{2} {}_0D_t^{-\beta}+
  \frac{1}{2}{}_tD_{T}^{-\beta}\big)u'(t)=\lambda u(t)+\nabla F(t,u(t)),\quad
  \text{a.e. } t\in[0,T], \\
 u(0)=0,\quad u(T)=0.
  \end{gather*}
 First for the eigenvalue problem associated with it, we
 prove that there is a sequence of positive and increasing real
 eigenvalues; a characterization of the first eigenvalue is also
 given. Then under different assumptions on the nonlinearity
 $F(t,u)$, we show the existence of weak solutions of the problem
 when $\lambda$ lies in various intervals. Our main tools are
 variational methods and critical point theorems.
\end{abstract}

\maketitle
\numberwithin{equation}{section}
\newtheorem{theorem}{Theorem}[section]
\newtheorem{lemma}[theorem]{Lemma}
\newtheorem{definition}[theorem]{Definition}
\newtheorem{remark}[theorem]{Remark}
\allowdisplaybreaks

\section{Introduction}

 As a generalization of  differentiation and integration to arbitrary
non-integer  order,  fractional calculus, is a significant tool
for solving  complex problems from various fields such as engineering, science,
viscoelasticity, diffusion and pure and applied mathematics.
 As the authors point out in \cite{MR}, there is hardly a field of science
or engineering that has remained untouched by this field. In the
past few years,  theory of fractional differential equation has been
investigated extensively, see  the monographs of Kilbas et al
\cite{KST}, Miller and Ross \cite{MR}, and Podlubny \cite{P},  Samko
\cite{SKM}, and the papers \cite {ABH, AN, BL, BZ, CT, ER, G, J, JZ,
JZ1,  LZ, s, Z, Z1} and the reference therein.

In \cite{ER}, Ervin and Loop investigated the steady state fractional advection
dispersion equation
\begin{equation}
\begin{gathered}
 -\frac{d}{dt} \Big(p  {}_0D_t^{-\beta}+  q\ _tD_{T}^{-\beta}\Big)u'(t)
 +b(t)u'(t)+c(t)u(t)=\nabla F(t,u(t)),\quad\text{a.e. }  t\in[0,T], \\
 u(0)=0,\quad u(T)=0, 
   \end{gathered}\label{0}
\end{equation}
by defining appropriate fractional derivative spaces, they established some
existence and uniqueness results of  the  problem. Recently, 
 there have been many papers dealing with the existence of solutions for this
 problem. Jiao and Zhou \cite{JZ} showed the variational structure of the
 problem
\begin{gather*}
 -\frac{1}{2}\frac{d}{dt} \Big(  {}_0D_t^{-\beta}+  {}_tD_{T}^{-\beta}\Big)u'(t)
=\nabla F(t,u(t)),\quad\text{ a.e. } t\in[0,T], \\
 u(0)=0,\quad u(T)=0. 
\end{gather*}
By using the least action principle and  Mountain Pass theorem, they obtained
some sufficient conditions for the existence of one solution. The
authors in \cite{CT,G, JZ1, s} further studied the existence and
multiplicity of solutions for the above problem or related problems
by critical point theory.

  Inspired by the results in \cite{ CT, ER, G, JZ, JZ1, s},  
we consider the existence of weak solution to the fractional
boundary-value problem
\begin{equation}\label{7}
   \begin{gathered}
 -\frac{1}{2}\frac{d}{dt} \Big(  {}_0D_t^{-\beta}+  \ _tD_{T}^{-\beta}\Big)u'(t)
=\lambda u(t)+\nabla F(t,u(t)),\quad\text{a.e. }  t\in[0,T], \\
 u(0)==0,\quad u(T)=0. 
   \end{gathered}
  \end{equation}
where $0<\beta<1$, ${}_0D_t^{-\beta}$ and $_tD_{T}^{-\beta}$
are the left and  right  fractional integrals of order $\beta$
respectively,  $\lambda\in \mathbb{R}$ is a parameter,
$F:[0,T]\times\mathbb{R}^N\to\mathbb{R}$, and 
$\nabla F(t,x)$ is the gradient of $F$ with respect to $x$.

First, we consider the  eigenvalue problem associates with
\eqref{7},
\begin{equation}
\begin{gathered}
 -\frac{1}{2}\frac{d}{dt} \Big(  {}_0D_t^{-\beta}+
  \ _tD_{T}^{-\beta}\Big)u'(t)=\lambda u(t) \quad\text{a.e. }  t\in[0,T], \\
 u(0)=0,\quad u(T)=0. \\
   \end{gathered}\label{50}
\end{equation}
By Riesz-Schauder theory, we prove that \eqref{50} possesses a
sequence of eigenvalues $\{\lambda_k\}$ with 
$0<\lambda_1\leq\lambda_2\leq\lambda_3\leq\dots$ and
  $\lambda_k\to\infty$ as $k\to\infty$. Then
 under the assumption that $F(t,u)$
  is superquadratic with respect to $u$,
we show that \eqref{7} has at least one nontrivial weak solution when
$\lambda<\lambda_1$ by using Mountain Pass theorem.
In the special case $\lambda=0$ our results extend \cite[Theorem 5.2]{JZ}.
When $\lambda\geq\lambda_1$, sufficient conditions for the existence
of one solution is also given by applying Linking theorem. 
We  obtain also the existence of  at least two weak solutions for every real
number $\lambda$ via  Brezis and Nirenberg's Linking theorem.
Furthermore, for every positive integer $k$, the existence criteria
of $k$ pairs of weak solutions when $\lambda>\lambda_k$ are
established by using Clark theorem. Our methods are different from 
those used in \cite{ CT, ER, G, JZ, JZ1, s}.


This article is organized as follows. 
In Section 2, some preliminaries are presented.
Section 3 presents the main result and its proof.

\section{Preliminaries}

To apply critical point theory for the existence of solutions for
 problem \eqref{7}, we shall state some basic notation
and results \cite{JZ1}, which will be used in the proof of our main
results.

 Throughout this paper, we denote $\alpha=1-\frac{\beta}{2}$, 
and assume that the following condition is satisfied.
\begin{itemize}
\item[(H1)]  $F(t,x)$ is measurable in $t$ for every $x\in\mathbb{R}^{N}$
and continuously differentiable in $x$ for a.e $t\in[0,T]$, and
there exist $a\in C(\mathbb{R}^{+},\mathbb{R}^{+})$,
$b\in L^1(0,T;\mathbb{R}^{+})$ such that 
\begin{equation}
|F(t,x)|\leq a(|x|)b(t),\quad 
|\nabla F(t,x)|\leq a(|x|)b(t)\label{5}
\end{equation} 
for all $x\in\mathbb{R}^{N}$ and $t\in[0,T]$.
\end{itemize}

The fractional derivative space $E^{\alpha}$ is defined by the
 completion of $C_0^{\infty}((0,T),\mathbb{R}^{N})$ with respect to the
 norm 
\[
 \|u\|=\Big(\int_0^T|u(t)|^2dt+\int_0^T|_0D_t^\alpha
u(t)|^2dt\Big)^{1/2},
\]
where  ${}_0D_t^\alpha$ is
  the $\alpha$-order left  Riemann-Liouville fractional derivative.
If $u\in E^{\alpha}$, then ${}_0D_t^\alpha u(t)$ exists a.e. in $[0,T]$.
The set $E^{\alpha}$ is a reflexive and separable Hilbert  space.

\begin{lemma}[\cite{JZ1}] \label{lem2}
 For all $u \in E^{\alpha}$, we have
\begin{gather}
\|u\|_{L^2}\leq\frac{T^\alpha}{\Gamma(\alpha + 1 )}
\|{}_0D_t^\alpha u\|_{L^2 },\label{2}
\\
\|u\|_{\infty}\leq \frac{T^{\alpha-\frac{1}{2}}}{\Gamma
(\alpha)(2\alpha-1 )^{1/2}}\|{}_0D_t^\alpha u\|_{L^2}.\label{3}
\end{gather}
\end{lemma}

According to \eqref{2}, one can consider $E^{\alpha}$ with respect
to the equivalent norm 
\begin{equation*}
\|u\|_{\alpha}=\|{}_0D_t^\alpha u\|_{L^2 } %\label{4}.
\end{equation*}

\begin{lemma}[\cite{JZ1}] \label{lem3}
  If the sequence $\{u_k\}$ converges weakly to $u$ in $E^{\alpha}$,
 i.e. $u_k \rightharpoonup u$. Then  $u_k \to u$ in $C([0,T],
\mathbb{R}^N)$, i.e. $\|u - u_k\|_{\infty}\to0$ as
$k\to \infty$.
\end{lemma}

 Similar to the proof of  \cite[Proposition 4.1]{JZ}, we have the
following property.

\begin{lemma}\label{lem4}  
For any $u\in E^\alpha$, we have 
\begin{equation} 
|\cos (\pi\alpha)|\|u\|_\alpha^2\leq -\int_0^T\big({_0D_t^{\alpha}}u(t),
{}_tD_T^{\alpha}u(t)\big)dt
\leq\frac{1}{|\cos(\pi\alpha)|}\|u\|_\alpha^ 2.\label{10}
\end{equation}
\end{lemma}

To obtain a weak solution of \eqref{7}, we assume that $u$
is a sufficiently smooth solution of \eqref{7}. 
 Multiplying \eqref{7} by an arbitrary $v\in C_0^{\infty}(0,T)$,
 we have
\begin{equation}
\begin{aligned}
&\int_0^T\Big(-\frac{1}{2}\frac{d}{dt}({_0D_t^{-\beta}}+{_tD_T^{-\beta}})u'(t),
v(t)\Big)-\lambda\big(u(t),v(t)\big)dt\\
&=\int_0^T\big(\nabla F(t,u(t)),\ v(t)\big)dt.
\end{aligned}\label{30}
\end{equation} 
Observe that
\begin{align*}
&-\frac{1}{2}\int_0^T\Big(\frac{d}{dt}({_0D_t^{-\beta}}u'(t)
+{_tD_T^{-\beta}}u'(t)), v(t)\Big)dt\\
&=\frac{1}{2}\int_0^T\Big(({_0D_t^{-\beta}}u'(t),v'(t))
 +({_tD_T^{-\beta}}u'(t), v'(t))\Big)dt\\
&=\frac{1}{2}\int_0^T\Big(({_0D_t^{-\beta/2}}
 u'(t),{_tD_T^{-\beta/2}}v'(t))
 +({_tD_T^{-\beta/2}}u'(t),{_0D_t^{-\beta/2}}v'(t))\Big)dt.
\end{align*}
As $u(0)=u(T)=v(0)=v(T)=0$, we have
\begin{gather*}
_0D_t^{-\beta/2}u'(t)={}_0D_t^{1-\frac{\beta}{2}}u(t),\quad
_tD_T^{-\beta/2}u'(t)=-{}_tD_T^{1-\frac{\beta}{2}}u(t),\\
_0D_t^{-\beta/2}v'(t)={}_0D_t^{1-\frac{\beta}{2}}v(t),\quad
_tD_T^{-\beta/2}v'(t)=-{}_tD_T^{1-\frac{\beta}{2}}v(t).
\end{gather*}
Then \eqref{30} is equivalent to
\begin{equation}
\begin{aligned}
&\int_0^T-\frac{1}{2}[\big( {_0D_t^{\alpha}}u(t),
_tD_T^{\alpha}v(t)\big)+\big({_tD_T^{\alpha}}u(t),
{_0D_t^{\alpha}}v(t)\big)]-\lambda \big(u(t),v(t)\big)dt\\
&=\int_0^T\big(\nabla F(t, u(t)),v(t)\big)dt.
\end{aligned}\label{31}
\end{equation}
 Since \eqref{31} is well defined
for $u,v\in E^{\alpha}$,  the weak solution of \eqref{7} can be
defined as follows.

\begin{definition} \label{def2.1} \rm
 A weak solution of \eqref{7} is a function $u\in E^{\alpha}$ such that
\begin{align*}
&\int_0^T-\frac{1}{2}\big[\big( {_0D_t^{\alpha}}u(t),
_tD_T^{\alpha}v(t)\big)+\big({_tD_T^{\alpha}}u(t),
{_0D_t^{\alpha}}v(t)\big)\big]\\
&-\lambda \big(u(t),v(t)\big)-\big(\nabla F(t, u(t)),\ v(t)\big)dt=0
\end{align*}
for every $v\in E^{\alpha}$.
\end{definition}

 We consider the functional $\varphi:E^{\alpha}\to \mathbb{R}$, defined by
\begin{equation}\varphi(u)=
\int_0^T\Big[-\frac{1}{2}\big({_0D_t^{\alpha}}u(t),
_tD_T^{\alpha}u(t)\big)-\frac{\lambda}{2}\big(u(t),u(t)\big)-F(t,
u(t))\Big]dt.\label{6}
\end{equation}
Then $\varphi$ is continuously differentiable under 
assumption (H1), and 
\begin{equation}
\begin{aligned}
\langle\varphi'(u),v\rangle
&=-\int_0^T\frac{1}{2}\left[\big( {_0D_t^{\alpha}}u(t),\
_tD_T^{\alpha}v(t)\big)+\big({_tD_T^{\alpha}}u(t),\
{_0D_t^{\alpha}}v(t)\big)\right]dt\\
&\quad -\int_0^T\lambda \big(u(t),v(t)\big)dt-\int_0^T\big(\nabla F(t,
u(t)),\ v(t)\big)dt
\end{aligned}\label{8}
\end{equation}
for $u, v\in E^\alpha$. Hence a critical point of $\varphi$ is a
weak solution of  \eqref{7}.

For our proofs, we need the following results in critical point
theory.

\begin{definition} \rm
Let $E$ be a real Banach space and $\varphi\in C^1(E,\mathbb{R})$.
We say that $\varphi$ satisfies the (PS) condition if any sequence
$\{u_m\}\subset E$ for which $\varphi(u_m)$ is bounded and
$\varphi'(u_m)\to 0$, as $m\to\infty$, posses a convergent subsequence.
\end{definition}

\begin{lemma}[{Mountain Pass theorem \cite[Theorem 2.2]{Rabinowitz}}] 
\label{lemma2.1}
 Let $E$ be a real Banach space and $\varphi\in C^1(E,\mathbb{R})$ satisfying  
(PS). Suppose $\varphi(0)=0$ and
\begin{itemize}
\item[(C1)] there are constants $\rho,\alpha>0$ such that $\varphi|_{\partial
B_\rho}\geq\alpha$, where $B_{\rho}=\{x\in E:\|x\|<\rho\}$,

\item[(C2)] there is an $e\in E\setminus \overline{B}_\rho$ such that
$\varphi(e)\leq0$.
\end{itemize}
Then $\varphi$ possesses a critical value $c\geq\alpha$. Moreover $c$
can be characterized as 
\[
c=\inf_{g\in\Gamma} \max_{u\in g([0,1])} \varphi(u),
\]
where $\Gamma=\{g\in C([0,1],E)| g(0)=0, g(1)=e\}$.
\end{lemma}

\begin{lemma}[{Linking theorem \cite[Theorem 5.3]{Rabinowitz}}]
 \label{lemma2.2} 
Let $E$ be a real Banach space with $ E=V\oplus X$, where $V$ is finite 
dimensional. Suppose $\varphi\in C^1(E,\mathbb{R})$, satisfies (PS),  and
\begin{itemize}
\item[(C1')] there are constants $\rho,\alpha>0$ such that $\varphi|_{\partial
B_\rho\cap X}\geq\alpha$, where $B_{\rho}=\{x\in E:\|x\|<\rho\}$,

\item[(C3)] there is an $e\in \partial B_1\cap X$ and $R>\rho$ such that
if $Q\equiv(\overline{B}_R\cap V)\oplus\{re|0 < r < R\}$, then
$\varphi |_{\partial Q}\leq0$.
\end{itemize}
Then $\varphi$
possesses a critical value $c\geq\alpha$, which can be characterized
as 
$$
c=\inf_{h\in\Gamma} \max_{u\in Q} \varphi(h(u)),
$$
 where $\Gamma=\{h\in C(\overline{Q},E): h=\mathrm{Id} \text{ on }  \partial Q\}$.
\end{lemma}

\begin{remark}\label{rem1}  \rm
It is easy to obtain the following conclusion. 
Suppose that $\varphi|_V \leq 0$ and there are
an $e\in\partial B_1 \cap X$ and an $\overline{R}\geq\rho$ such that
$\varphi(u)\leq 0$ for $u\in V\oplus \operatorname{span}\{e\}$ and 
$\|u\|\geq \overline{R}$. Then for any large $R, Q$ as defined in (C3)
satisfies $\varphi |_{\partial Q}\leq0$.
\end{remark}

\begin{lemma}[{Clark theorem \cite[Theorem 9.1]{Rabinowitz}}] \label{lemma2.3}
Let $E$ be a real Banach space, $\varphi\in C^1(E,\mathbb{R})$, with
$\varphi$ even, bounded from below, and satisfying (PS). Suppose
$\varphi(0)=0$, there is a set $E'\subset E$ such that $E'$ is
homeomorphic to $S^{j-1} $ ($j-1$ dimension unit sphere) by an odd
map, and $sup_{E'}\varphi<0$. Then $\varphi$ possesses at least $j$
distinct pairs of critical points.
\end{lemma}

Next we have the Brezis and Nirenberg's linking theorem.

\begin{lemma}[\cite{BN}] \label{lemma2.4}
Let $E$ have a direct sum decomposition $E=X\oplus Y$, where $\dim X
<\infty$, and $\varphi$ be a $ C^1$ functional on $E$ with
$\varphi(0)=0$, satisfying  (PS) and assume that, for some $r>0$,
$$
\varphi(x)\leq0,\; \forall x\in X,\quad
\|x\|\leq r,\; \varphi(y)\geq0,\; \forall y\in Y,\; \|y\|\leq r.
$$
 Assume also that $\varphi$ is bounded below and $\inf_E\varphi<0$.
Then $\varphi$ has at least two nonzero critical points.
\end{lemma}

\section{Main results}

First we consider the  eigenvalue problem
\begin{equation}
\begin{gathered}
 -\frac{1}{2}\frac{d}{dt} \Big({}_0D_t^{-\beta}+ {}_tD_{T}^{-\beta}\Big)u'(t)
=\lambda u,\quad\text{a.e. } t\in[0,T], \\
 u(0)=0,\quad u(T)=0\,.
\end{gathered}\label{11}
  \end{equation}
Its weak solution $u\in E^\alpha$ satisfies
\begin{equation}
-\int_0^T\frac{1}{2}\left[\big( {_0D_t^{\alpha}}u(t),\
_tD_T^{\alpha}v(t)\big)+\big({_tD_T^{\alpha}}u(t),\
{_0D_t^{\alpha}}v(t)\big)\right]dt=\int_0^T\lambda (u(t),v(t))dt
 \label{28} 
\end{equation}
  for every $v\in E^\alpha$.


\begin{theorem} 
Each eigenvalue of \eqref{11} is real and if we
  repeat each eigenvalue according to its multiplicity, we h
$0<\lambda_1\leq\lambda_2\leq\lambda_3\leq\dots$ and
  $\lambda_k\to\infty$ as $k\to\infty$. $\lambda_1$
  can be characterized as
\begin{equation}
\lambda_1=\inf_{u\in  E^\alpha\setminus\{0\}}
\frac{-\int_0^T  \big( {_0D_t^{\alpha}}u(t),{}_tD_T^{\alpha}u(t)\big)dt}
{\int_0^T(u(t),u(t))dt}.
  \label{12}
  \end{equation}
Furthermore,   there exists an orthogonal basis $\{w_k\}_{k=1}^{\infty}$ of
$E^\alpha$, where  $w_k\in E^\alpha$ is an eigenfunction
  corresponding to $\lambda_k$ for $k=1,2,\dots$.
\end{theorem}

\begin{proof}
 For $u\in E^\alpha$, let
$$
\|u\|_1=\Big(-\int_0^T\big({_0D_t^{\alpha}}u(t),{_tD_T^{\alpha}}u(t)
\big)dt\Big)^{1/2}.
$$
From \eqref{10}, we have
$$
|\cos\pi\alpha|^{1/2}\|u\|_{\alpha}\leq\|u\|_1
\leq|\cos\pi\alpha|^{-\frac{1}{2}}\|u\|_{\alpha}.
$$
So $\|\cdot\|_1$ is an equivalent norm on $E^{\alpha}$, while
$E^{\alpha}$ is a Banach space with this new norm, and there is an
inner product induced by $\|\cdot\|_1$, we denote
  $$
(u,v)_1=-
\int_0^T\frac{1}{2}\big[\big( {_0D_t^{\alpha}}u(t),\
{{_tD_T^{\alpha}}}v(t)\big)+\big({_tD_T^{\alpha}}u(t),\
{_0D_t^{\alpha}}v(t)\big)\big]dt,\quad
 u,v\in E^\alpha.
$$ 
Then $E^\alpha$ is a Hilbert space with this inner product.

Next, we will transform \eqref{28} into a problem about symmetric
compact operator.
From H\"{o}lder inequality and  \eqref{2}, for  given
$u\in L^2(0,T)$ and any $v\in E^\alpha$,
\begin{align*}
\big|\int_0^T(u, v) dt\big|
&\leq\|u\|_{L^2}\|v\|_{L^2}\\
&\leq\frac{T^\alpha}{\Gamma(\alpha + 1 )} \|u\|_{L^2}\|v\|_{\alpha }\\
&\leq\frac{T^\alpha}{\Gamma(\alpha + 1 )|\cos\pi\alpha|^{1/2}} \|u\|_{L^2}\|v\|_1.
\end{align*}
In view of the Riesz theorem, there exists a unique $w\in E^\alpha$ such that
$$
\int_0^T(u,v)dt=(w,v)_1,\quad \forall v\in E^\alpha.
$$
If we define the operator $K:L^2(0,T)\to E^\alpha$ as $Ku=w$,
then 
$$
\|Ku\|_\alpha\leq\frac{T^\alpha}{\Gamma(\alpha + 1
)|\cos\pi\alpha|^{1/2}} \|u\|_{L^2}
$$
 and $K$ is a bounded linear operator from $L^2(0,T)$ to $E^\alpha$. Let
$S:E^\alpha\to L^2(0,T)$ be an embedding operator, by Lemma
\ref{lem3}, $S$ is compact. Thus \eqref{28} is  equivalent to
$$
(u,v)_1=(\lambda w,v)_1=(\lambda KSu,v)_1,\quad \forall v\in E^\alpha.
$$
That is,
 $$
(I-\lambda KS)u=0.
$$
Since $E^\alpha$ is separable and $KS$ is symmetric and compact, by
Riesz-Schauder theory, we know that all eigenvalue $\{\lambda_k\}$
of $KS$ are  positive real  numbers and there are corresponding
eigenfunctions which make up an orthogonal basis of $E^\alpha$ and
\eqref{12} holds.
\end{proof}

\begin{lemma}\label{lem5}
Suppose the following condition holds
\begin{itemize}
 \item[(H2)] there are constants $\mu>2$ and $R>0$ such that, for 
$|x|\geq R$,
\begin{equation}
0<\mu F(t,x)\leq (x,\ \nabla F(t,x)).\label{13}
\end{equation}
\end{itemize} 
Then $\varphi$ satisfies the (PS) condition.
\end{lemma}

\begin{proof} Let $\{u_n\}\subset E^\alpha$, $\{\varphi(u_n)\}$ be
bounded and $\varphi'(u_n)\to0$.  First we show that
$\{u_n\}$ is bounded.
From  \eqref{13}, we know that there exist constants
 $a_1, a_2>0$ such that 
\begin{equation}
F(t,x)\geq  a_1|x|^{\mu}-a_2,\quad t\in [0,T],\; x\in \mathbb{R}^{N}.\label{19}
\end{equation}
Since $\mu>2$, then for  $\varepsilon>0$, $u\in E^\alpha$ and by Young's
inequality, we have
\begin{equation*}
\|u\|_{L^2}^2\leq T^{\frac{\mu-2}{\mu}}\|u\|_{L^{\mu}}^2
\leq C(\varepsilon)+\varepsilon\|u\|_{L^{\mu}}^{\mu} %\label{18}
\end{equation*} 
where $ C(\varepsilon)\to\infty$ as $\varepsilon\to0$.

Choose $2<\mu_1<\mu$, and denote $\tilde{\lambda}=\lambda$ for
$\lambda>0$, and $\tilde{\lambda}=0$ otherwise. Then for large $n$
and choose $\varepsilon$ small enough,
\begin{align*}
&\mu_1\varphi(u_n)-(\varphi'(u_n),u_n)\\
&=(1-\frac{\mu_1}{2})\int_0^T\big( {_0D_t^{\alpha}}u_n(t),\
_tD_T^{\alpha}u_n(t)\big)dt+\lambda(1-\frac{\mu_1}{2})\|u_n\|_{L^2}^2\\
&\quad +\int_{|u_n|\geq R}( (u_n(t),\nabla F(t,u_n(t)))-\mu_1
F(t,u_n(t)))dt\\
&\quad +\int_{|u_n|<R}(
(u_n(t),\nabla F(t,u_n(t)))-\mu_1 F(t,u_n(t)))dt\\
&\geq (\frac{\mu_1}{2}-1) |\cos(\pi\alpha)|
 \|u_n\|_\alpha^2-\tilde{\lambda}(1-\frac{\mu_1}{2})\|u_n\|_{L^2}^2
+(\mu-\mu_1)a_1\|u_n\|_{L^{\mu}}^{\mu}\\
&\quad -(\mu-\mu_1)Ta_2+c\\
&\geq (\frac{\mu_1}{2}-1) |\cos
(\pi\alpha)|\|u_n\|_\alpha^2-\tilde{\lambda}(1-\frac{\mu_1}{2})(C(\varepsilon)
+\varepsilon\|u_n\|_{L^{\mu}}^{\mu})+(\mu-\mu_1)a_1\|u_n\|_{L^{\mu}}^{\mu}\\
&\quad -(\mu-\mu_1)Ta_2+c.
\end{align*}
 where $c$ is a constant. So this implies that $\{u_n\}$ is bounded since
 $\varepsilon$ is
small enough.

From the reflexivity of $E^\alpha$, we may extract a weakly
convergent subsequence that, for simplicity, we call $\{u_n\}$,
$u_n\rightharpoonup u$, then $\|u_n-u\|_{\infty}\to0$. Next,
we  prove that $\{u_n\}$ strongly converges to $u$. By (H1), we know
 that
\begin{equation}
\int_{0}^{T}\big(\ u_n(t)-u(t),\nabla
F(t,u_n(t))-\nabla F(t,u(t))\big)dt\to0 \quad \text{as }
n\to\infty.\label{20}
 \end{equation}
From \eqref{6}, we have
\begin{equation}
\begin{aligned}
&(\varphi'(u_n)-\varphi'(u),u_n-u)\\
&=-\int_0^T\big( {{_0D_t^{\alpha}}}(u_n(t)-u(t)),
{}_tD_T^{\alpha}(u_n(t)-u(t))\big)dt\\
&\quad -\lambda\int_0^T((u_n(t)-u(t)),(u_n(t)-u(t)))dt\\
&\quad -\int_{0}^{T}\big(\ u_n(t)-u(t),\nabla F(t,u_n(t))-\nabla F(t,u(t))\big)dt \\
&\geq |\cos(\pi\alpha)|\|u_n-u\|_\alpha^2-\tilde{\lambda}
T\|u_n-u\|_{\infty}^2\\
&\quad -\int_{0}^{T}\big(\ u_n(t)-u(t),\nabla
F(t,u_n(t))-\nabla F(t,u(t))\big)dt.
\end{aligned}\label{21}
\end{equation}
From $\varphi'(u_n)\to0$ and $u_n\rightharpoonup u$,  we
obtain that
\begin{equation}(\varphi'(u_n)-\varphi'(u),u_n-u)\to0
\quad\text{as }n\to\infty.\label{22}
\end{equation}
In view of \eqref{20}, \eqref{21} and \eqref{22}, it is easy to see
that $\| u_n-u\|_\alpha\to0$ as
 $n\to\infty$.  Therefore $\varphi$ satisfies the (PS) condition.
\end{proof}

\begin{theorem}\label{th1}
If {\rm (H2)} holds and
\begin{itemize}
\item[(H3)] 
\[
\limsup_{|x|\to0}\frac{F(t,x)}{|x|^2}\leq
\frac{(\Gamma(\alpha+1))^2|\cos(\pi\alpha)|}{4T^{2\alpha}}
(1-\frac{\tilde{\lambda}}{\lambda_1})
\]
 uniformly for $t\in[0,T]$,
where $\tilde{\lambda}=\lambda$ for
$\lambda>0$, and $\tilde{\lambda}=0$ otherwise.
\end{itemize}
Then for $\lambda<\lambda_1$, \eqref{7} has at least one nontrivial
weak solution.
\end{theorem}

\begin{proof}
The proof relies on the Mountain Pass theorem. It is clear that 
$\varphi\in C^1(E^\alpha,R)$,
$\varphi(0)=0$, and $\varphi$ satisfies the (PS) condition  from Lemma
\ref{lem5}.


From (H3), for 
$$
\varepsilon_1=\frac{(\Gamma(\alpha+1))^2|\cos(\pi\alpha)|}{4T^{2\alpha}}
(1-\frac{\tilde{\lambda}}{\lambda_1}),
$$
 there exists a constant $\delta>0$, such that
 $$
F(t,x)\leq\varepsilon_1 |x|^2,\quad t\in[0,T],\;|x|<\delta.
$$
Let $u\in E^\alpha$ with $\|u\|_\alpha\leq\frac{\Gamma
(\alpha)(2\alpha-1 )^{1/2}\delta}{T^{\alpha-\frac{1}{2}}}$,
then by \eqref{3}, $\|u\|_{\infty}\leq\delta$, and from \eqref{12}
and \eqref{2}, we have
\begin{align*}
\varphi(u)
&= \int_0^T\Big[-\frac{1}{2}\big({{_0D_t^{\alpha}}}u(t),\
_tD_T^{\alpha}u(t)\big)-\frac{\lambda}{2}(u(t),u(t))-F(t, u(t))\Big]dt\\
&\geq\int_0^T-\frac{1}{2}\big({_0D_t^{\alpha}}u(t),
 {}_tD_T^{\alpha}u(t)\big)dt+\frac{\tilde{\lambda}}{2\lambda_1}
 \int_0^T\big({_0D_t^{\alpha}}u(t),
 {}_tD_T^{\alpha}u(t)\big)dt-\varepsilon_1\|u\|_{L^2}^2\\
&\geq(1-\frac{\tilde{\lambda}}{\lambda_1})
 \frac{|\cos(\pi\alpha)|}{2}\|u\|_{\alpha}^2
-\frac{\varepsilon_1 T^{2\alpha}}{(\Gamma(\alpha+1))^2}\|u\|_{\alpha}^2\\
&=(1-\frac{\tilde{\lambda}}{\lambda_1})
 \frac{|\cos(\pi\alpha)|}{4}\|u\|_{\alpha}^2.
\end{align*}
If we choose 
$\rho=\frac{\Gamma (\alpha)(2\alpha-1 )^{1/2}\delta}{T^{\alpha-\frac{1}{2}}}$ and
$\varrho=(1-\frac{\tilde{\lambda}}{\lambda_1})\frac{|\cos(\pi\alpha)|\rho^2}{4}$,
then $\varphi|_{\partial B_{\rho}}\geq\varrho$.

  Let $w_1\in E^\alpha$ be an eigenfunction
corresponding to  $\lambda_1$ in \eqref{12}, and choose $r>0$, it follows from
\eqref{19} that
\begin{align*}
\varphi(rw_1)&=\int_0^T\Big[-\frac{r^2}{2}\big({_0D_t^{\alpha}}w_1(t),
{}_tD_T^{\alpha}w_1(t)\big)-\frac{r^2\lambda}{2}(w_1(t),w_1(t))-F(t,
rw_1(t))\Big]dt\\
&\leq\frac{\lambda_1r^2}{2}\|w_1\|_{L^2}^2-\frac{\lambda
r^2}{2}\|w_1\|_{L^2}^2-a_1r^{\mu}\|w_1\|_{L^{\mu}}^{\mu}+a_2T,
\end{align*}
which implies that $\varphi(rw_1)\to-\infty$ as
$r\to\infty$.

 The above discussions show that $\varphi$ has at least one nontrivial
critical point, thus \eqref{7} has at least one
nontrivial weak solution for $\lambda<\lambda_1$.
\end{proof}

Note that when $\lambda=0$, Theorem \ref{th1} extends the results in 
\cite[Theorem 5.2]{JZ}.

\begin{theorem}\label{th2} 
Suppose {\rm (H2)} holds and
\begin{itemize}
\item[(H4)] $F(t,x)\geq0$ for all $x
\in \mathbb{R}^N\setminus\{0\}$.

\item[(H5)] $F(t,x)=o(|x|^2)$ as $x\to0$.
\end{itemize}
Then the problem \eqref{7} possesses a nontrivial weak solution for
$\lambda\geq\lambda_1$.
\end{theorem}

\begin{proof}
 We will show that the functional $\varphi$ satisfies the hypotheses in
Lemma \ref{lemma2.2} when $\lambda\geq\lambda_1$.

Lemma \ref{lem5} tell us
that $\varphi$ satisfies the (PS) condition.
Since $\lambda\geq\lambda_1$, we can assume $\lambda\in [\lambda_k,
\lambda_{k+1})$ for some $k\in\mathbb{N}$. Set
$V=\operatorname{span}\{w_1,\dots,w_k\}$ and $X=V^{\bot}$, where $\{w_j\}$ are
eigenfunctions of \eqref{11} corresponding to the eigenvalues
$\{\lambda_j\}$.

From (H5)  and \eqref{2}, for a small positive number $\varepsilon_2$, there
exists a constant $\delta_1>0$, such that, for $u\in E^{\alpha}$
with $\|u\|_{\infty}<\delta_1$, we have
 $$
\int_0^TF(t,u)dt\leq \varepsilon_2\|u\|_{L^2}^2
\leq\frac{\varepsilon_2T^{2\alpha}} {(\Gamma(\alpha + 1 ))^2}\|u\|_\alpha^2.
$$
  Hence for $u\in X,$  with $\|u\|_{\infty}\leq\delta_1$, we have
\begin{align*}
\varphi(u)&=
\int_0^T\Big[-\frac{1}{2}\big({_0D_t^{\alpha}}u(t),\
_tD_T^{\alpha}u(t)\big)-\frac{\lambda}{2} (u(t),u(t))-F(t,u(t))\Big]dt\\
&\geq-\frac{1}{2}\int_0^T\big({_0D_t^{\alpha}}u(t),\
_tD_T^{\alpha}u(t)\big)dt+\frac{\lambda}{2\lambda_{k+1}}\int_0^T\big({_0D_t^{\alpha}}u(t),\
_tD_T^{\alpha}u(t)\big)dt\\
&\quad -\frac{\varepsilon_2T^{2\alpha}}{(\Gamma(\alpha + 1 ))^2}\|u\|_\alpha^2 \\
&\geq-\frac{1}{2}(1-\frac{\lambda}{\lambda_{k+1}})\int_0^T\big({_0D_t^{\alpha}}u(t),\
_tD_T^{\alpha}u(t)\big)dt-\frac{\varepsilon_2T^{2\alpha}}{(\Gamma(\alpha
+ 1 ))^2}\|u\|_\alpha^2\\
&\geq\frac{|\cos(\pi\alpha)|}{2}(1-\frac{\lambda}{\lambda_{k+1}})\|u\|_{\alpha}^2
-\frac{\varepsilon_2T^{2\alpha}}{(\Gamma(\alpha
+ 1 ))^2}\|u\|_\alpha^2.
\end{align*}
If we choose $\varepsilon_2$ small enough, we can get
$\rho,\varrho>0$ such that $\varphi|_{\partial B_\rho\cap
X}\geq\varrho$, and $\varphi$ satisfies $(C_1^{'})$ in Lemma
\ref{lemma2.2}.

To check (C3) in Lemma \ref{lemma2.2}, it suffices to verify
the conditions in Remark \ref{rem1}. In fact, for $u\in V$, by (H4), we have
\begin{equation}
\begin{aligned}
\varphi(u)
&=\int_0^T\Big[-\frac{1}{2}\big({_0D_t^{\alpha}}u(t),\
_tD_T^{\alpha}u(t)\big)-\frac{\lambda}{2} (u(t),u(t))-F(t,u(t))\Big]dt\\
&\leq-\frac{1}{2}\int_0^T\big({_0D_t^{\alpha}}u(t),\
_tD_T^{\alpha}u(t)\big)dt+\frac{\lambda}{2\lambda_{k}}\int_0^T\big({_0D_t^{\alpha}}u(t),\
_tD_T^{\alpha}u(t)\big)dt\\
&\leq-\frac{1}{2}(1-\frac{\lambda}{\lambda_{k}})\int_0^T\big({_0D_t^{\alpha}}u(t),\
_tD_T^{\alpha}u(t)\big)dt\\
&\leq\frac{|\cos(\pi\alpha)|(\lambda_k-\lambda)}{2\lambda_{k}}\|u\|_{\alpha}^2
<0.
\end{aligned}\label{26}
\end{equation}
Let $u_0=\frac{w_{k+1}}{\|w_{k+1}\|_{\alpha}}$, then  for
$u\in V\oplus span\{u_0\}$, we obtain
\begin{align*}
\varphi(u)
&= \int_0^T\Big[-\frac{1}{2}\big({_0D_t^{\alpha}}u(t),\
_tD_T^{\alpha}u_0(t)\big)-\frac{\lambda}{2}(u(t),u(t))-F(t, u(t))\Big]dt\\
&\leq\frac{\|u\|_\alpha^2}{2|\cos(\pi\alpha)|}
 -\frac{\lambda}{2}\|u\|_{L^2}^2-a_1\|u\|_{L^\mu}^{\mu}+a_2T.
\end{align*}
Since $\mu>2$, and $V\oplus span\{u_0\}$ is a finite dimensional space on
 which all norms are equivalent. So we  obtain $\varphi(u)\to-\infty$
as $\|u\|_{\alpha}\to\infty, u\in V\oplus span\{u_0\}$.
 This implies that  for any large $R, Q$ as defined in
(C3),  $\varphi |_{\partial Q}\leq0$.

By Lemma \ref{lemma2.2}, $\varphi$ has at least a nontrivial
critical point, so \eqref{7} possesses a nontrivial weak solution
for $\lambda\geq\lambda_1$.
\end{proof}

\begin{remark} \label{rmk3.6} \rm
In fact, (H5) implies (H3), so when $\lambda<\lambda_1$, Theorem
\ref{th1} gives the conclusion, that is, under the assumptions of
(H2), (H4) and (H5), Equation \eqref{7} possesses at least one nontrivial
weak solution for $\lambda\in\mathbb{R}$.
\end{remark}

\begin{theorem} If {\rm (H1)} holds and
\begin{itemize}
\item[(H6)]There exist $b_1,b_2>0$, and $\eta\in(0,2)$
such that
$$
F(t,x)\leq-\frac{\lambda}{2}|x|^2+ b_1|x|^\eta+b_2,\quad
 x\in \mathbb{R}^N,\; t\in[0,T].
$$

\item[(H7)] There are $k\in \mathbb{N}$ and $r_1>0$ such that, 
for $|x|\leq r_1$
\begin{equation}
\frac{\lambda_k-\lambda}{2}|x|^2\leq
F(t,x)\leq\frac{\lambda_{k+1}-\lambda}{2}|x|^2,\quad t\in[0,T].
\label{27}
\end{equation}
\end{itemize}
Then  \eqref{7} possesses at least two nontrivial weak solutions for
$\lambda\in \mathbb{R}$.
\end{theorem}

\begin{proof}
First we show that $\varphi$ is bounded from below.
Since $\eta\in(0,2)$, for $u\in E^\alpha$, by (H6) and \eqref{3},
we have
\begin{equation}
\begin{aligned}\varphi(u)
&= \int_0^T\Big[-\frac{1}{2}\big({_0D_t^{\alpha}}u(t),\
_tD_T^{\alpha}u(t)\big)-\frac{\lambda}{2} (u(t),u(t))-F(t,u(t))\Big]dt
\\
&\geq-\frac{1}{2}\int_0^T\big({_0D_t^{\alpha}}u(t),\
_tD_T^{\alpha}u(t)\big)dt-b_1T\|u\|_{\infty}^\eta-b_2T
\\
&\geq\frac{|\cos(\pi\alpha)|}{2}\|u\|_{\alpha}^2
 -\frac{b_1T^{\eta(\alpha-\frac{1}{2})+1}}{(\Gamma (\alpha))^\eta(2\alpha-1)
^{\eta/2}}\|u\|_\alpha^\eta-b_2T.
\end{aligned} \label{25}
\end{equation}
This implies $\varphi$ is bounded from below. If $\{u_n\}$ is a (PS)
sequence, then $\{u_n\}$ is bounded from \eqref{25}. Similar to the
later part proof  of Lemma \ref{lem5}, we can get that $\varphi$
satisfies the (PS) condition.

Set $V=\operatorname{span}\{w_1,\dots,w_k\}$ and $X=V^{\bot}$, 
where $\{w_j\}$ are eigenfunctions of \eqref{11}. 
From (H7), for $u\in V$ with
$\|u\|_{\alpha}\leq\frac{\Gamma (\alpha)(2\alpha-1 )^{1/2}r_1}
{T^{\alpha-\frac{1}{2}}}$, then $\|u\|_{\infty}\leq r_1$, and
\begin{equation}
\begin{aligned}
\varphi(u)&=\int_0^T\left[-\frac{1}{2}\big({_0D_t^{\alpha}}u(t),\
_tD_T^{\alpha}u(t)\big)-\frac{\lambda}{2} (u(t),u(t))-F(t,u(t))\right]dt\\
&\leq-\frac{1}{2}\int_0^T\big({_0D_t^{\alpha}}u(t),\
_tD_T^{\alpha}u(t)\big)dt-\frac{\lambda_k}{2}\|u\|_{L^2}^2
\leq 0.
\end{aligned} \label{26b}
\end{equation}
For $u\in X$ with $\|u\|_{\infty}\leq r_1$, by (H7), we have
\begin{equation}
\begin{aligned}
\varphi(u)
&=\int_0^T\Big[-\frac{1}{2}\big({_0D_t^{\alpha}}u(t),\
_tD_T^{\alpha}u(t)\big)-\frac{\lambda}{2} (u(t),u(t))-F(t,u(t))\Big]dt\\
&\geq-\frac{1}{2}\int_0^T\big({_0D_t^{\alpha}}u(t),\
_tD_T^{\alpha}u(t)\big)dt-\frac{\lambda_{k+1}}{2}\|u\|_{L^2}^2
\geq 0.
\end{aligned} \label{27b}
\end{equation}
If $\inf_{u\in E^\alpha} \varphi(u)\geq0$, then
$\varphi(u)=0$ for all $u\in V$ with
$\|u\|_{\alpha}\leq \frac{\Gamma (\alpha)(2\alpha-1 )^{1/2}r_1}
{T^{\alpha-\frac{1}{2}}}$, which implies that all
$u\in V$ with $\|u\|_{\alpha}\leq \frac{\Gamma (\alpha)(2\alpha-1
)^{1/2}r_1}{T^{\alpha-\frac{1}{2}}}$ are solutions of
\eqref{7}.
If  $\inf_{u\in E^\alpha} \varphi(u)<0$, by
Lemma \ref{lemma2.4}, we get that $\varphi$ has at least two
nontrivial weak solutions for $\lambda\in(\lambda_k,\lambda_{k+1})$.
\end{proof}

\begin{theorem} \label{thm3.8}
Suppose {\rm (H6)} holds and
\begin{itemize}
\item[(H8)] There exist $\varepsilon_3, r_2>0$,
such that $F(t,x)\geq\varepsilon_3$ for $|x|\leq r_2$.
\item[(H9)] $F(t,x)=F(t,-x)$.
\end{itemize}
Then  for $k=1,2,\dots$,  problem \eqref{7} possesses at least $k$ distinct
pairs of weak solutions for $\lambda>\lambda_k$.
\end{theorem}

\begin{proof}
It is clear that $\varphi(0)=0$ and  from (H9),
$\varphi(u)$ is even. (H6) and \eqref{25} show that $\varphi$ is
bounded from below and satisfies the (PS) condition.

Let $\{w_j\}$ be the eigenfunctions of \eqref{11} corresponding to
$\{\lambda_j\}$. Choose 
\[
E'=\{u|u=\sum\limits_{j=1}^k\alpha_jw_j,
\sum_{j=1}^k\alpha_j^2
=\frac{\Gamma (\alpha)(2\alpha-1 )^{1/2}r_2}{T^{\alpha-\frac{1}{2}}}\},
\]
then $E'$ is homeomorphic to the $k-1$ dimension unit sphere $S^{k-1} $ 
by an odd map.

Assume $u\in E'$, then $\|u\|_{\alpha}=\frac{\Gamma
(\alpha)(2\alpha-1 )^{1/2}r_2}{T^{\alpha-\frac{1}{2}}}$,
so $\|u\|_{\infty}\leq r_2$, via (H8), we have
\begin{align*}
\varphi(u)
&=\int_0^T\Big[-\frac{1}{2}\big({_0D_t^{\alpha}}u(t),\
_tD_T^{\alpha}u(t)\big)-\frac{\lambda}{2} (u(t),u(t))-F(t,u(t))\Big]dt\\
&\leq-\frac{1}{2}\int_0^T\big({_0D_t^{\alpha}}u(t),\
_tD_T^{\alpha}u(t)\big)dt-\frac{\lambda_k}{2}\|u\|_{L^2}^2-\varepsilon_3\\
&\leq-\varepsilon_3.
\end{align*}
 This implies that $\sup_{E'}\varphi<0$. And
by Clark theorem,  $\varphi$ possesses at least $k$ distinct pairs
of critical points which correspond to the weak solutions of
\eqref{7}.
\end{proof}

\subsection*{Acknowledgments}
This research was supported grant NECT-12-0246 and grant 
lzujbky-2013-k02
from the program for New Century Excellent Talent in Universities.

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\end{document}