\documentclass[reqno]{amsart}
\usepackage{hyperref}

\AtBeginDocument{{\noindent\small
\emph{Electronic Journal of Differential Equations},
Vol. 2012 (2012), No. 191, 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 2012 Texas State University - San Marcos.}
\vspace{9mm}}

\begin{document}
\title[\hfilneg EJDE-2012/191\hfil Eigenvalue problems of fractional order]
{Basic results on nonlinear eigenvalue problems of fractional order}

\author[M. Al-Refai \hfil EJDE-2012/191\hfilneg]
{Mohammed Al-Refai}  % in alphabetical order

\address{Mohammed Al-Refai \newline
Department of Mathematical Sciences \\
United Arab Emirates University \\
P.O. Box 17551, Al Ain, UAE}
\email{m\_alrefai@uaeu.ac.ae}

\thanks{Submitted November 20, 2011. Published October 31, 2012.}
\subjclass[2000]{34A08, 34B09, 35J40}
\keywords{Fractional differential equations; boundary-value problems;
\hfill\break\indent
maximum principle; lower and upper solutions; Caputo fractional derivative}

\begin{abstract}
 In this article, we discuss the basic theory of boundary-value problems
 of fractional order $1 < \delta < 2$ involving the Caputo derivative.
 By applying the maximum  principle, we obtain necessary conditions for
 the existence of eigenfunctions, and show analytical lower and upper bounds
 estimates of the eigenvalues. Also we obtain a sufficient condition
 for the non existence of ordered solutions,  by transforming
 the problem into equivalent integro-differential equation.
 By the method of lower and upper solution, we obtain a general
 existence and uniqueness result: We generate two well defined monotone
 sequences of lower and upper solutions which converge uniformly to the
 actual solution of the problem.
 While some fundamental results are obtained, we leave others as 
 open problems stated in a conjecture.
\end{abstract}

\maketitle
\numberwithin{equation}{section}
\newtheorem{theorem}{Theorem}[section]
\newtheorem{lemma}[theorem]{Lemma}
\newtheorem{corollary}[theorem]{Corollary}
\newtheorem{definition}[theorem]{Definition}
\newtheorem{conjecture}[theorem]{Conjecture}
\newtheorem{remark}[theorem]{Remark}
\allowdisplaybreaks

\section{Introduction}

In this article, we study the eigenvalue problem of fractional order
\begin{gather}
D^{\delta} u(t)+g(t)u'+h(t) u=-\lambda k(t,u), \quad t\in (0,1), \; 1 <
\delta < 2, \label{eq1}\\
u(0)-\alpha u'(0)=0, \quad u(1)+\beta u'(1)=0, \quad \alpha, \beta \ge
0,\label{eq2}
\end{gather}
where $k\in C^1([0,1]\times \mathbb{R}), g$ and $h\in C[0,1]$, and
$D^\delta$ is the Caputo fractional derivative of order $\delta$.

 In  recent years a great interest was devoted to the study of boundary-value problems
of fractional order.
There are several definitions of  fractional derivative. However, the most popular
ones are the Riemann-Liouville and Caputo fractional derivatives.
The two definitions differ only in the order of evaluation.
In the Caputo definition, we first compute an ordinary derivative then a
fractional integral, while  in the
Riemann-Liouville definition the operators are reversed.
 In this article, we use the Caputo's
fractional derivative since mathematical modeling of many
physical problems requires initial and boundary conditions.
These demands are satisfied using the  Caputo fractional derivative.
For more details we refer the reader to \cite{kilbas,podlubny} and
references therein.

The importance of fractional boundary-value problems stems from
the fact that they model various applications in fluid mechanics,
visco-elasticity, physics, biology  and economics which can not
be modeled by differential equations with integer derivatives
 \cite{atanackovic,caputo,podlubny}.

The existence and uniqueness results of fractional boundary-value problems
have been investigated by many authors using different
 techniques \cite{agarwal,agarwal2,ref,bai1,bai2,furati,furati2,lak3,shuqin,zhang}.
The basic theory of fractional differential equations involving
the Riemann-Liouville derivative of order
   $0 <\delta < 1$, has been investigated in \cite{lak1,lak2} by
the classical approach of differential equations. Also, the ideas of comparison
principle and the method of lower and upper solutions are applied to prove
a general  result of existence and uniqueness  of solutions in
     \cite{lak3}. By means of Schauder Fixed Point Theorem, Zhang  \cite{shuqin}
proved the existence of solutions for the following
boundary-value problem of fractional order, involving Caputo's derivative
\begin{gather*}
D_t^\delta u(t)=g(t,u), \quad 0 < t < 1, \; 1 <\delta < 2, \\
u(0)=a \neq 0, \quad u(1)=b\neq 0.
\end{gather*}
Also, Al-Refai and Hajji \cite{ref}  established existence and uniqueness results
by  generating monotone iterative sequences of lower and upper solutions
that converge uniformly  to the actual solution of the above problem.
In a recent work  Qi and Chen \cite{qi}  studied analytically an eigenvalue
 problem of order $ 0 <\delta <1$, with left and
right fractional derivatives, which models a bar of finite
length with long range interactions.  Using the spectral theory of self-adjoint
compact  operators in Hilbert spaces, they proved that the problem has a
countable simple real eigenvalues and the corresponding
eigenfunctions form a complete orthogonal system in the Hilbert space $L^2$.

The Sturm-liouville eigenvalue problem has played an important role in modeling
many physical problems.
The theory of the problem is well developed and many results have been obtained
concerning the eigenvalues and corresponding eigenfunctions.
However, up to our knowledge, there are no analytical studies for the eigenvalues
and eigenfunctions of the fractional Sturm-Liouville eigenvalue problems of
order $1<\delta < 2$. Following the classical approach of the theory of
 differential equations of integer order and by means of the maximum principle
and the method of lower and upper solutions \cite{pao,protter}, this
 paper presents new results about the eigenvalues and eigenfunctions of the
eigenvalue problem \eqref{eq1}-\eqref{eq2}.

This article is organized as follows. In the next section, we present
basic definitions and results of fractional derivative.
In Section 3, we present a new positivity lemma,
 a uniqueness result and bounds for the eigenvalues of the problem.
In Section 4, we present a sufficient condition for
  the non existence of ordered solutions.
In Section 5, we obtain an existence and uniqueness result using the method
   of lower and upper solutions.
We then discuss the linear eigenvalue problem and highlight
future research directions in Section 6.
We close up with some concluding remarks in Section 7.

\section{Preliminaries}

In this section, we present the definitions and some preliminary results
 of the Riemmann-Liouville fractional integral and the  Caputo fractional derivative.
 We then give the definition of lower and upper solutions of
 the problem  \eqref{eq1}-\eqref{eq2}.

\begin{definition} \label{def2.1} \rm
A real function $f(t), t>0$, is said to be in the space $C_{\mu}, \mu \in \mathbb{R}$
if there exists a real number $p>\mu$, such that
$f(t)=t^p f_1(t)$, where $f_1(t)\in C[0,\infty)$, and it is said to be in the
 space $C_\mu^{m}$ if $f^{(m)}\in C_\mu$,  $m\in \mathbb{N}$.
\end{definition}

\begin{definition} \label{def2.2} \rm
The left Riemann-Liouville fractional integral of order $\delta >0$,
of a function $f\in C_{\mu}, \mu \ge -1$, is defined by
\begin{equation} \label{e2.1}
I^{\delta} f(t)=\frac{1}{\Gamma(\delta)}\int_0^t
(t-s)^{\delta-1}f(s)ds, \quad t>0.
\end{equation}
\end{definition}

The following result will be used throughout the text.

\begin{lemma}\label{bound}
If $f(t)\in C[0,1]$, then $I^\delta f(t)$ exists and $\lim_{t\to 0} I^{\delta} f(t)=0$.
\end{lemma}

\begin{proof}
We have $r(s)=(t-s)^{\delta-1}\ge 0$ is integrable on $[0,t]$, since $\delta >0$.
 Applying the mean value theorem for integrals
 we have
 $$
\int_0^t (t-s)^{\delta-1}  f(s) ds=f(\xi) \int_0^t (t-s)^{\delta-1}  ds
=f(\xi) \frac{t^\delta}{\delta}, \quad \text{for some } 0<\xi <t.
$$
Thus,
 $$
\lim_{t\to 0}I^{\delta} f(t)=\lim_{t\to 0} f(\xi) \frac{t^\delta}{\Gamma(\delta+1)}=0.
$$
\end{proof}

\begin{definition} \label{def2.3} \rm
For $\delta >0$, $m-1 <\delta< m$, $m\in \mathbb{N}$, $t>0$, and $f\in C_{-1}^m$,
 the left Caputo fractional derivative  is defined by
\begin{equation}
D^\delta f(t)=\frac{1}{\Gamma(m-\delta)}\int_0^t (t-s)^{m-1-\delta}
f^{(m)}(s) ds,
\label{caputodefn}
\end{equation}
where $\Gamma$ is the well-known Gamma function.
\end{definition}

The Caputo derivative defined in \eqref{caputodefn} is related to
the Riemann-Liouville fractional integral, $I^{\delta}$, of order
$\delta \in \mathbb{R}^+$, by 
\[
D^{\delta}f(t)= I^{m-\delta} f^{(m)}(t).
\]
It is known (see \cite{kilbas}) that
\begin{gather}
I^{\delta}(D^{\delta} f(t))=f(t)-\sum_{k=0}^{m-1}c_k t^k, \label{ID}\\
D^{\delta}I^{\delta} f(t)=f(t), \label{DI}
\end{gather}
where in \eqref{ID}, $c_k=\frac{f^{(k)}(0+)}{k!}$, $0\leq k\leq m-1$.

\begin{definition}[\cite{ref}] \label{def2.4} \rm
A function $v(t)\in C^2[0,1]$ is called a lower
solution of the problem \eqref{eq1}-\eqref{eq2} if it satisfies
\begin{equation}
P(v)=D^\delta v(t)+ g(t)v'+ h(t) v+\lambda k(t,v)\ge 0, \quad t\in (0,1),
\; 1 < \delta < 2, \label{lseq}
\end{equation}
and
\begin{equation}
 v(0)-\alpha v'(0) \le 0, \quad v(1)+\beta v'(1) \le 0.
 \label{lsbc}
\end{equation}
 Analogously, a function $w(t)\in C^2[0,1]$ is called
 an upper solution if it satisfies \eqref{lseq}-\eqref{lsbc} with
 reversed inequalities.
\end{definition}

If $v(t) \le w(t)$,  for all $t\in [0,1]$, we say that
$v$ and $w$ are ordered lower and upper solutions.

\section{General results and estimates of the eigenvalues}

In this section we present   a  positivity lemma which will be used
throughout the text. We then
prove general results concerning the lower and upper solutions of the
eigenvalue problem  \eqref{eq1}-\eqref{eq2}.
At the end, we present necessary conditions for the existence of eigenfunctions
 and give analytical estimates on the bounds of the eigenvalues.
We have the following results, see \cite{alrefai}.

\begin{theorem}\label{tt1}
Assume  $f\in C^2[0,1]$ attains its  minimum at $t_0\in (0,1)$, then
$$
(D^\delta f)(t_0)\ge \frac{1}{\Gamma(2-\delta)}
\Big[ (\delta-1) t_0^{-\delta}(f(0)-f(t_0))-t_0^{1-\delta} f'(0)\Big], \quad
 \text{for all }  1<\delta<2.
$$
\end{theorem}

\begin{corollary}\label{cor1}
Assume  $f\in C^2[0,1]$ attains its  minimum at $t_0\in (0,1)$, and $f'(0)\le 0$.
Then $(D^\delta f)(t_0)\ge 0$, for all $1<\delta<2$.
\end{corollary}

In the following we state and prove a positivity  result which will
be used throughout the text.

\begin{lemma}[Positivity Result] \label{lemma1}
Let $z(t)\in C^2[0,1], \mu(t,z)\in C\big([0,1]\times \mathbb{R})$
and $\mu(t,z)<0, \forall\ t\in (0,1)$. If $z(t)$ satisfies the inequalities
\begin{gather}
 D^\delta z(t) + a(t) z'(t)+\mu(t,z) z \le 0,\quad t\in(0,1),\label{lemma1eq}\\
 z(0)-\alpha z'(0) \ge 0, \quad \text{and} \quad z(1)+\beta z'(1)\ge 0,
\label{lemma1bc}
 \end{gather}
where  $a(t)\in C[0,1]$ and $\alpha,\beta \ge 0$, then $z(t)\ge 0$, for all
$t\in [0,1]$ provided $\alpha \ge \frac{1}{\delta-1}$.
\end{lemma}

\begin{proof}
Assume that the conclusion is false, then $z(t)$ has absolute minimum at some
 $t_0 $ with $z(t_0)<0$. Let $t_0\in (0,1)$, then
$z'(t_0)=0$. In the following we prove that $(D^{\delta}z)(t_0)\ge 0$.
By Corollary  \ref{cor1} the result is true if $z'(0) \le 0$.
If $z'(0) >0$, by Theorem \ref{tt1} there holds
\begin{align*}
\Gamma(2-\delta) (D^\delta z)(t_0)
&\ge (\delta-1) t_0^{-\delta}(z(0)-z(t_0))-t_0^{1-\delta} z'(0)\\
&=t_0^{-\delta}\Big((\delta-1)(z(0)-z(t_0))-t_0z'(0)\Big).
\end{align*}
Since $\alpha (\delta-1)\ge 1$ and from the boundary condition
 $z(0)\ge \alpha z'(0)$, we have
 $$
(\delta-1)(z(0)-z(t_0))\ge (\delta-1)(\alpha z'(0)-z(t_0))
\ge z'(0)-(\delta-1) z(t_0).
$$
Thus,
$$
(\delta-1)(z(0)-z(t_0))-t_0 z'(0) \ge z'(0)-(\delta-1) z(t_0)-t_0 z'(0)
=z'(0)(1-t_0)-(\delta-1) z(t_0).
$$
Since $z'(0)>0, 0<t_0<1$ and $z(t_0)<0$, we have     $(D^{\delta} z)(t_0)\ge 0$.
The above results together with  $ \mu(t_0,z(t_0)) < 0$, imply
$$
(D^\delta z) (t_0) + a(t_0)z'(t_0)+ \mu(t_0,z(t_0)) z(t_0)
=(D^\delta z)(t_0) + \mu(t_0,z(t_0))z(t_0) > 0,
$$
which contradicts \eqref{lemma1eq}. If $t_0=0$, by simple maximum
principle, $z'(0^+)\ge 0$. Applying the boundary condition
$z(0)-\alpha z'(0)\ge 0$, we have $z(0)\ge 0$ and a
contradiction is reached. Similarly, if $t_0=1$, then simple maximum
principle implies $z'(1^-) \le 0$. The boundary condition
$z(1)+\beta z'(1^-) \ge 0$ yields $z(1) \ge 0$ and a
contradiction is reached.
\end{proof}

\begin{theorem}\label{ordered}
Consider  problem \eqref{eq1}--\eqref{eq2}.
If $h(t)+\lambda \frac{\partial k(t,u)}{\partial u}< 0$, for all
 $u\in C^2[0,1]$ and $t \in (0,1)$, then for $\alpha \ge \frac{1}{\delta-1}$ we have
 \begin{enumerate}
 \item Any lower and upper solutions are ordered.
 \item The problem \eqref{eq1}-\eqref{eq2} possesses at most one solution.
\end{enumerate}
\end{theorem}

\begin{proof}
(1) Let $v$ and $w$ respectively, be any lower and upper solutions of the problem.
 We have
\begin{equation} \label{eq3}
\begin{gathered}
D^\delta v(t)+g(t) v'(t)+h(t)v+\lambda k(t,v) \ge 0, \quad t\in (0,1), \\
v(0)-\alpha v'(0)\leq 0,\quad  v(1)+\beta v'(1)\leq 0,
\end{gathered}
\end{equation}
 and
\begin{equation}
\begin{gathered}
D^\delta w(t)+g(t) w'(t)+h(t)w+\lambda k(t,w) \le 0, \quad t\in (0,1),
 \label{eq4}\\
w(0)-\alpha w'(0)\ge 0,\quad  w(1)+\beta w'(1)\ge 0.
\end{gathered}
\end{equation}
Subtracting  \eqref{eq3} from  \eqref{eq4} and applying the mean value theorem,
 we have
\begin{gather*}
D^\delta (w -v)+g(t)(w'-v')+h(t)(w-v)+\lambda (k(t,w)-k(t,v)) \le 0, \\
D^\delta (w -v)+g(t)(w'-v')+\Big(h(t)+\lambda
\frac{\partial k}{\partial {u}}(\xi)\Big)(w-v) \le  0,
\end{gather*}
where $\xi=\gamma w+(1-\gamma) v$, $0 \le \gamma \le 1$.
 Let $z=w-v$, then $z$ satisfies
$$
D^\delta z+g(t) z'+\Big(h(t)+\lambda \frac{\partial k}{\partial {u}}(\xi)\Big) z\le 0,
$$
with $z(0)-\alpha z'(0)\ge 0$ and $ z(1)+\beta z'(1)\ge 0$.
 Since $h(t)+\lambda\frac{\partial k}{\partial {u}}(\xi)  <0$,
by the positivity result, Lemma \ref{lemma1},  $z \ge 0$, and thus $w\ge v$.

(2) Let $u_1$ and $u_2$ be two solutions of \eqref{eq1}-\eqref{eq2}. We
have
\begin{gather}
D^\delta u_1+g(t) u_1'+h(t)u_1+\lambda k(t,u_1)= 0,\label{eqq1}\\
D^\delta u_2+g(t) u_2'+h(t)u_2+\lambda k(t,u_2)= 0,\label{eqq2}
\end{gather}
with $u_1(0)-\alpha u_1'(0)=u_2(0)-\alpha u_2'(0)=0$, and
$u_1(1)+\beta u_1'(1)=u_2(1)+\beta u_2'(1)=0$.
By subtracting  \eqref{eqq2} from  \eqref{eqq1}, applying the mean value theorem,
and substituting $z=u_1-u_2$, we have
\begin{equation} \label{eeh11}
D^\delta z+g(t) z'+\Big(h(t)+\lambda \frac{\partial k}{\partial{u}}(\xi)\Big) z= 0,
\end{equation}
for some $\xi$ between $u_1$ and $u_2$,
with
\begin{equation} 
z(0)-\alpha z'(0)=0 \quad\text{and}\quad z(1)+\beta z'(1)= 0.\label{nec}
\end{equation}
Since $h(t)+\lambda\frac{\partial k}{\partial {u}}(\xi) <0$,
by the positivity result, Lemma \ref{lemma1},
we have $z\ge 0$. On the other hand  \eqref{eeh11}-\eqref{nec} are also
satisfied by $-z$ and  by  Lemma \ref{lemma1}, we have $-z\ge 0$.
Thus, $z=0$. This proves that $u_1=u_2$ and problem
\eqref{eq1}\--\eqref{eq2} has at most one solution.
\end{proof}

The following corollary gives analytical lower and upper bounds estimates
 of the eigenvalues.

\begin{corollary}\label{estimates}
Consider the eigenvalue problem \eqref{eq1}-\eqref{eq2}, with
$k(t,0)=0$  and $\alpha \ge \frac{1}{\delta-1}$.
 We have the following necessary conditions for the
existence of an eigenfunction.
\begin{itemize}
\item[(1)] If there exists a negative constant $\xi$ such that 
$\frac{\partial k}{\partial u}\le \xi <0$,
then $\lambda \le \sup\{-h/\frac{\partial k}{\partial u}\}$.

\item[(2)] If there exists a positive constant $\mu$ such that
 $\frac{\partial k}{\partial u}\ge \mu >0$,
then $\lambda \ge \inf\{-h/\frac{\partial k}{\partial u}\}$.
\end{itemize}
\end{corollary}

\begin{proof}
(1) If $\lambda > \sup\{-h/\frac{\partial k}{\partial u}\}$, then
 $\lambda > -h/ \frac{\partial k}{\partial u}$ for all $t\in [0,1]$. Since
$\frac{\partial k}{\partial u}<0$, we have $h(t)+\lambda
\frac{\partial k}{\partial u} <0$. Thus the eigenvalue problem
possesses at most one solution. Since $k(t,0)=0$, it can be easily
seen that  $u=0$ is a solution. Thus the eigenvalue problem has only
the trivial solution and hence no eigenfunction.

(2) If $\lambda <\inf\{-h/\frac{\partial k}{\partial u}\}$, then
 $\lambda < -h/\frac{\partial k}{\partial u}$ for all $t\in [0,1]$. Since
$\frac{\partial k}{\partial u}> 0$, we have $h(t)+\lambda
\frac{\partial k}{\partial u} <0$. Thus the eigenvalue problem
possesses only the trivial  solution and hence no eigenfunction.
\end{proof}

\section{Existence of ordered solutions}

In this section, we present a sufficient condition for the non existence 
of ordered solutions of the eigenvalue problem \eqref{eq1}-\eqref{eq2}. This
new result will be needed  to prove a uniqueness result in the next section.

\begin{definition} \label{def} \rm
Let $u_1\neq u_2$ be two solutions of 
\eqref{eq1}-\eqref{eq2}. We say that $u_1$ and $u_2$ are ordered
solutions, if either $u_1\le u_2$ or $u_2\le u_1$  for all $t\in [0,1]$.
\end{definition}

\begin{lemma}\label{gensol}
Consider  problem \eqref{eq1}-\eqref{eq2} with $g,h \in C[0,1]$  and 
$k\in C^1([0,1]\times \mathbb{R})$. A function $u(t)\in C^2[0,1]$ is a solution 
of the problem  if and only if it is a solution of the integro-differential equation
\begin{equation}
\begin{split}
u(t)&=\frac{\alpha+t}{\Gamma(\delta)(\alpha+\beta+1)}\Big(\int_0^1
(1-s)^{\delta-1}H(s,u)ds\\
&\quad +\beta(\delta-1)\int_0^1(1-s)^{\delta-2}H(s,u) ds \Big)
 -\frac{1}{\Gamma(\delta)}\int_0^t(t-s)^{\delta-1}
H(s,u)ds,
\end{split}\label{integro}
\end{equation}
where $H(s,u)=g(s) u'(s)+h(s) u(s) +\lambda k(s,u)$.
\end{lemma}

\begin{proof}
Let $u(t)$ be a solution of \eqref{eq1}. Applying the operator
$I^{\delta}$ to both sides of \eqref{eq1} and using \eqref{ID}, we
obtain 
\begin{equation} \label{genu} %\label{55}
\begin{split}
u(t)
&= c_0+c_1t-I^\delta H(t,u(t))
 =c_0+c_1t-\frac{1}{\Gamma(\delta)}\int_0^t(t-s)^{\delta-1}H(s,u) ds\\
&= c_0+c_1t-\frac{1}{\Gamma(\delta)}\int_0^t
 (t-s)^{\delta-1}(g(s) u'(s)+h(s) u(s)+\lambda k(s,u))ds.
\end{split}
\end{equation}
Thus, $u(0)=c_0$ and
$u(1)=c_0+c_1-\frac{1}{\Gamma(\delta)}\int_0^1 (1-s)^{\delta-1}H(s,u) ds$.
Differentiating \eqref{genu} yields
\begin{equation}
\begin{split}
u'(t)&= c_1-D^1 I^{\delta}H(t,u)=c_1-D^1 I^1 I^{\delta-1}H(t,u)\\
 &=c_1-I^{\delta-1}H(t,u)
 = c_1-\frac{1}{\Gamma(\delta-1)}\int_0^t (t-s)^{\delta-2}H(s,u) ds.
\end{split}\label{66}
\end{equation}
Since $\delta-1>0$ and $H(s,u)\in C[0,1]$ by Lemma \ref{bound}, we have  $u'(0)=c_1$,
 and
$$
u'(1)=c_1-\frac{1}{\Gamma(\delta-1)}\int_0^1 (1-s)^{\delta-2}H(s,u) ds.
$$
Applying the boundary conditions \eqref{eq2} and using the fact that
 $\Gamma(\delta)=(\delta-1)\Gamma(\delta-1)$, we find that $ c_0-\alpha c_1=0$,
and
\begin{equation}
c_0+c_1-\frac{1}{\Gamma(\delta)}\int_0^1 (1-s)^{\delta-1} H(s,u) ds
+\beta\Big(c_1-\frac{\delta-1}{\Gamma(\delta)}\int_0^1
(1-s)^{\delta-2} H(s,u) ds\Big)=0.\label{w1}
\end{equation}
Substituting $c_0=\alpha c_1$ in  \eqref{w1} yields
\begin{equation}\label{c1}
c_1=\frac{1}{\Gamma(\delta)(\alpha+\beta+1)}\Big(\int_0^1
(1-s)^{\delta-1}H(s,u)ds+\beta(\delta-1)\int_0^1
(1-s)^{\delta-2}H(s,u) ds \Big).
\end{equation}
Substitution of $c_0$ and $c_1$ back into \eqref{genu} gives
\begin{align*}
u(t)&=\frac{\alpha+t}{\Gamma(\delta)(\alpha+\beta+1)}\Big(\int_0^1
(1-s)^{\delta-1}H(s,u)ds\\
&\quad +\beta(\delta-1)\int_0^1(1-s)^{\delta-2}H(s,u) ds \Big)
 -\frac{1}{\Gamma(\delta)}\int_0^t(t-s)^{\delta-1}H(s,u)ds.
\end{align*}
Conversely, Let $u(t)$ be a solution of \eqref{integro}.  Substituting
$$
\nu=\frac{1}{(\alpha+\beta+1)}\Big(\int_0^1
(1-s)^{\delta-1}H(s,u)ds+\beta(\delta-1)\int_0^1
(1-s)^{\delta-2}H(s,u) ds \Big)
$$
 yields
\begin{equation}\label{nu}
u(t)=\frac{1}{\Gamma(\delta)}\Big( \nu (\alpha+t)
-\int_0^t(t-s)^{\delta-1} H(s,u) ds\Big).
\end{equation}
Applying the differential operator $D^1$, we have
\begin{equation} \label{nuu}
\begin{split}
u'(t)
&=\frac{1}{\Gamma(\delta)}\nu-D I^\delta H(t,u)
 =\frac{1}{\Gamma(\delta)}\nu-I^{\delta-1}H(t,u) \\
&=\frac{1}{\Gamma(\delta)}\Big( \nu -(\delta-1)\int_0^t(t-s)^{\delta-2} H(s,u) ds\Big).
\end{split}
\end{equation}
 Thus $u(0)=\frac{\alpha \nu}{\Gamma(\delta)}$ and by Lemma \ref{bound},
 $u'(0)=\frac{\nu}{\Gamma(\delta)}$ and hence; $u(0)-\alpha u'(0)=0$.
Also,
\begin{align*}
u(1)+\beta u'(1)
&=\frac{1}{\Gamma(\delta)}\Big(\nu(\alpha+1)-\int_0^1(1-s)^{\delta-1}H(s,u)ds\\
&\quad +\beta \nu -\beta (\delta-1)\int_0^1(1-s)^{\delta-2} H(s,u) ds \Big) \\
&=\frac{1}{\Gamma(\delta)}\Big(\nu(\alpha+\beta+1)-[\int_0^1(1-s)^{\delta-1}H(s,u)ds\\
&\quad +\beta (\delta-1)\int_0^1(1-s)^{\delta-2} H(s,u) ds ] \Big) \\
&=\frac{1}{\Gamma(\delta)}\Big(\nu(\alpha+\beta+1)-\nu(\alpha+\beta+1\Big)=0.
\end{align*}
 Next, since $D^\delta[\nu(\alpha+t)]=0, \ 1<\delta<2$, application of
$D^{\delta}$ to both sides of \eqref{nu},  gives
\[
D^{\delta}u = -\frac{1}{\Gamma(\delta)} D^{\delta}
\Big[\int_0^t (t-s)^{\delta-1}H(s,u(s)) ds\Big]
=-D^\delta I^\delta H(t,u)=-H(t,u).
\]
Thus, $u$ satisfies \eqref{eq1} and the proof is complete.
\end{proof}

We have the following important result.

\begin{theorem}\label{ordered2}
 Consider  problem \eqref{eq1}-\eqref{eq2} with 
$g,h \in C[0,1],k\in C^1([0,1]\times \mathbb{R}), u\in C^2[0,1], $ and 
$g(t)\ge 0, \ t\in [0,1]$. If $h(t)+\lambda \frac{\partial k}{\partial u} \ge \eta> 0$, 
for some positive constant $\eta$, then there exists $\alpha_0>0$ such that 
the problem has no ordered solutions for $\alpha\ge \alpha_0$.
\end{theorem}


\begin{proof}
Let $u_1 \le u_2$ be two solutions of \eqref{eq1}-\eqref{eq2}. We have
\begin{gather*}
u_1(t)= c_0+c_1t-I^\delta H(t,u_1(t))=c_0+c_1 t
 -\frac{1}{\Gamma(\delta)}\int_0^t (t-s)^{\delta-1} H(s,u_1) ds, \\
u_2(t)= d_0+d_1 t-I^\delta H(t,u_2(t))=d_0+d_1 t
 -\frac{1}{\Gamma(\delta)}\int_0^t (t-s)^{\delta-1} H(s,u_2) ds,
\end{gather*}
where $c_1=u'_1(0)$, $d_1=u'_2(0)$,
and  $H(s,u(s))=g(s) u'(s)+h(s)u(s)+\lambda k(s,u(s))$. 
Let $z(t)=u_2(t)-u_1(t) \ge 0 \in [0,1]$.
We have
\begin{equation}
\begin{gathered}
z(t)= d_0-c_0+(d_1-c_1)t-I^\delta \Big(H(t,u_2(t))-H(t,u_1(t))\Big)\\
z(0)= \alpha z'(0) \quad \text{and} \quad z(1)=-\beta z'(1).
\end{gathered}\label{boundary}
\end{equation}
Thus,
\begin{equation}
\begin{split}
z'(t)&= d_1-c_1-D^1 I^\delta \Big(H(t,u_2)-H(t,u_1)\Big)\\
&= u'_2(0)-u'_1(0)-D I^1\Big[I^{\delta-1} \Big(H(t,u_2)-H(t,u_1)\Big)\Big] \\
&=  z'(0)-\frac{1}{\Gamma(\delta-1)}\int_0^t(t-s)^{\delta-2}
 \Big(H(s,u_2)-H(s,u_1)\Big) ds.
\end{split}\label{77}
\end{equation}
 Substituting $z'=u_2'-u_1'$ in \eqref{77} and applying the mean value theorem
  yields
\begin{equation}
\begin{split}
z'(t)
&= z'(0)-\frac{1}{\Gamma(\delta-1)}\int_0^t(t-s)^{\delta-2} \Big(g(s)(u_2'-u_1')\\
 &\quad +h(s)(u_2-u_1)+\lambda[k(s,u_2)-k(s,u_1)]\Big) ds \\
&= z'(0)-\frac{1}{\Gamma(\delta-1)}\int_0^t(t-s)^{\delta-2}
 \Big(g(s)z'(s)+[h(s)+\lambda \frac{\partial k}{\partial u}(\xi)] z(s) \Big)  ds,
\end{split}\label{zz}
\end{equation}
for some $\xi$ between $u_1$ and $u_2$.
 Assume by contradiction $z\neq 0$, then $z(t)$ has a positive maximum in $[0,1]$.
 Let $t_0\in [0,1]$ be the first point at which $z$ has a positive
maximum. If $t_0=0$, by simple maximum principle,
$z'(0^+) \le 0$. Applying the boundary condition in \eqref{boundary}
 we have $z(0)\le 0$, and a contradiction is reached.
Similarly, if $t_0=1$, then $z'(1^-)\ge 0$. Applying the boundary condition
 in \eqref{boundary} yields $z(1)\le 0$ and a contradiction is reached.
Thus $t_0\in(0,1)$.
We have  $z(t_0)> 0$, $ z'(t_0)=0$ and  since $z'(0)\ge 0$, $z'(t)\ge 0$,
for all $ t\in [0,t_0]$.
 We consider two cases for $z(0)$:
 case 1; $z(0)=0$ and case 2; $z(0)=\zeta>0$.
If $z(0)=0$, by the boundary condition \eqref{boundary}, $z'(0)=0$.
Substituting the above results in \eqref{zz} together with $g(s)\ge 0, s\in [0,t_0]$
and $h(s)+\lambda \frac{\partial k}{\partial u}(\xi)\ge \eta > 0$
 yields $z'(t_0)< 0$, which contradicts $z'(t_0)=0$.
 Now, let $z(0)=\zeta>0$. We have
\begin{equation}
\begin{split}
\kappa&=\frac{1}{\Gamma(\delta-1)}\int_0^{t_0}(t_0-s)^{\delta-2} \Big(g(s)z'(s)+[h(s)+\lambda \frac{\partial
k}{\partial u}(\xi)] z(s) \Big)  ds \\
&> \frac{\eta \zeta}{\Gamma(\delta-1)} \int_0^{t_0}(t_0-s)^{\delta-2}ds
= \frac{\eta \zeta}{\Gamma(\delta-1)}\frac{t_0^{\delta-1}}{\delta-1}
=\frac{\eta \zeta}{\Gamma(\delta)}t_0^{\delta-1}.
\end{split}\label{i}
\end{equation}
Substituting \eqref{i} in \eqref{zz}, for
 $\alpha >\alpha_0=\frac{\Gamma(\delta)}{\eta} t_0^{1-\delta}$, we have
\begin{equation}
z'(t_0)<\frac{\zeta}{\alpha}-\frac{\eta \zeta}{\Gamma(\delta)}t_0^{\delta-1}<0,
\end{equation}
and a contradiction is reached. Thus $z=0$ and the proof is complete.
\end{proof}

\section{Existence and uniqueness result}

In this section we apply the method of lower and upper solutions to 
establish an existence and uniqueness result
 of the eigenvalue problem \eqref{eq1}-\eqref{eq2}.
 Given ordered lower and upper solutions, $v^{(0)}(t)$ and $w^{(0)}(t)$ respectively,  
define the set
$$
[v^{(0)},w^{(0)}]=\{f\in C^2[0,1]: v^{(0)} \le f \le w^{(0)}\},
$$
and let
$Q_1(f)=f(0)-\alpha f'(0)$,  $Q_2(f)=f(1)+\beta f'(1)$.

\begin{theorem}\label{constructionthm}
Consider the boundary-value problem \eqref{eq1}-\eqref{eq2} with
 $\alpha \ge \frac{1}{\delta-1}$. Let
$v^{(0)}$ and $w^{(0)}$ be an initial ordered lower and upper
solutions of \eqref{eq1}-\eqref{eq2} and assume that there exists 
a positive constant $c$ such that
\begin{equation}
 -c < h(t)+\lambda \frac{\partial k}{\partial u}\quad \text{for all }
u\in [v^{(0)},w^{(0)}] \text{ and } t \in [0,1].
\end{equation}
 Let  $t \in (0,1)$, let 
$v^{(j)}, w^{(j)}$, $j\ge 1$, be, respectively, the solutions of
\begin{gather}
-D^{\delta} v^{(j)}-g(t) D v^{(j)}+ c \ v^{(j)}
=(h(t)+ c) v^{(j-1)}+\lambda k(t,v^{(j-1)}),
\label{vkeq}\\
Q_1(v^{(j)})= Q_2(v^{(j)})=0, \label{vkbc} 
\end{gather}
 and 
\begin{gather}
-D^{\delta} w^{(j)}-g(t) D w^{(j)}+ c \ w^{(j)}
 = (h(t)+ c) w^{(j-1)}+ \lambda k(t,w^{(j-1)}), \label{wkeq}\\
 Q_1(w^{(j)})= Q_2(w^{(j)})=0. \label{wkbc}
\end{gather}
Then we have
\begin{itemize}
\item[(1)] The sequence  $v^{(j)}$, $j\geq 1$, is  an increasing sequence 
of lower solutions of \eqref{eq1}-\eqref{eq2}.
\item[(2)] The sequence  $w^{(j)}$, $j\geq 1$, is  a decreasing sequence
 of upper solutions of \eqref{eq1}-\eqref{eq2}.
\item[(3)]   $v^{(j)} \leq w^{(j)}$, for all $j\geq1$.
\item[(4)] The sequences
$\{v^{(j)}\}$ and $\{w^{(j)}\}$, $j\ge 0$, converge uniformly
 to $v^*$ and $w^*$, respectively, with $v^*\le w^*$.
\end{itemize}
\end{theorem}

The proof is a  simple generalization to the one obtained in \cite{ref}. 
We shall skip it  as not to impede the presentation of the main results 
and make the presentation easier to follow.

\begin{theorem}  \label{uniqueness} 
Consider  problem \eqref{eq1}-\eqref{eq2} with
 $k(t,0)\neq 0$. Let $v^{(j)}$ and $w^{(j)}$, $j\ge 0$, be
as defined in Theorem \ref{constructionthm}.  Then problem \eqref{eq1}-\eqref{eq2} 
has a unique nontrivial  solution $u\in [v^{(0)},w^{(0)}]$
provided one of the following conditions holds
\begin{itemize}
\item[(H1)] $h(t)+\lambda \frac{\partial k}{\partial u} <
0$, for all $u\in [v^{(0)},w^{(0)}]$, $t\in (0,1)$ and 
$\alpha \ge \frac{1}{\delta-1}$.

\item[(H2)] $h(t)+\lambda \frac{\partial k}{\partial u} \ge \eta > 0$, for all 
$u\in [v^{(0)},w^{(0)}]$ and $t\in (0,1)$, $g(t)\ge 0$ and
 $\alpha\ge \alpha_0$ is sufficiently large.
\end{itemize}
\end{theorem}

\begin{proof}
 First we prove that $v^*$ and $w^*$
are solutions to \eqref{eq1}-\eqref{eq2}.
Since $\{v^{(j)}\}$ converges
uniformly and applying the result in \cite{ref}, we have
$$
-\lim_{j\to \infty} D^\delta v^{(j)}=- D^\delta \lim_{j\to \infty}
v^{(j)}=-D^\delta v^*.
$$
Also, the uniform convergence of the sequence $\{v^{(j)}\}$ together 
with the continuity of $k(t,u)$ yields
$$
\lim_{j\to \infty}k(t,v^{(j)})=k(t,v^{*}).
$$
Applying the above results in \eqref{vkeq}, we have
\begin{gather*}
\lim_{j\to \infty}\Big(-D^{\delta} v^{(j)}- g(t) D v^{(j)}+ c \ v^{(j)}\Big)
=\lim_{k\to\infty}\Big((h(t)+c)v^{(j-1)}+ \lambda k(t, v^{(j-1)})\Big), 
\\
-D^{\delta} v^{*}- g(t) D v^{*}+ c \ v^{*}
=(h(t)+c)v^{*}+ \lambda k(t, v^{*}).
\end{gather*}
Thus, 
$$
D^{\delta} v^{*}+g(t) D v^{*}+ h(t)v^{*}
= - \lambda k(t, v^{*})
$$
which together with $Q_1(v^*)=Q_2(v^*)=0$ proves that
$v^*$ is  a solution to \eqref{eq1}-\eqref{eq2}. Similar arguments can be 
applied to show that $w^*$ is a solution
 to \eqref{eq1}-\eqref{eq2}. If (H1) holds, by Theorem \ref{ordered}, 
the solution is unique and hence
 $v^*=w^*=u$ is the unique solution of \eqref{eq1}-\eqref{eq2}
in $[v^{(0)},w^{(0)}]$. If (H2) holds then by Theorem \ref{ordered2} there 
is no  ordered solutions. Since $v^*$
 and $w^*$ are solutions of the problem with $v^*\le w^*$ then $v^*=w^*=u$.
Lastly, the condition $k(t,0)\neq 0$ guarantees that $u\neq 0$.
\end{proof}

\begin{remark} \label{rmk5.1} \rm
The condition (H1)  in Theorem \ref{uniqueness}  guarantees the uniqueness 
of solutions for the eigenvalue problem \eqref{eq1}-\eqref{eq2} with 
integer order $\delta=2$, (see \cite[p. 104]{pao}), while the condition
 (H2) is new.
\end{remark}


\section{The linear eigenvalue problem}

As a special case of problem \eqref{eq1}-\eqref{eq2}, we consider the linear 
eigenvalue problem
\begin{gather}
D^{\delta} u(t)+g(t)u'+h(t)u=-\lambda r(t) u, \quad t\in (0,1), \; 1 <\delta < 2,
\label{eqeq1}\\
u(0)-\alpha u'(0)=0, \quad u(1)+\beta u'(1)=0, \label{eqeq2}
\end{gather}
where $k(t,u)=r(t) u$. Here we discuss two cases of $r(t)$. 
First $r(t)>0$ and there exists a positive constant $\mu$ such that 
$r(t)\ge \mu >0$, and second $r(t)<0$ and there
exists a negative constant $\xi$ such that $r(t)\le \xi <0$. 
Since $k(t,0)=0$ by Corollary \ref{estimates} we have
for $\alpha \ge 1/(\delta-1)$,
\begin{equation}
\begin{gathered}
\lambda \ge \inf_{t\in [0,1]}\Big(-\frac{h(t)}{r(t)}\Big),\quad \text{if }  r(t)> 0,\\
\lambda \le \sup_{t\in [0,1]}\Big(-\frac{h(t)}{r(t)}\Big),\quad
\text{if }  r(t)< 0.
\end{gathered} \label{gst22}
\end{equation}
Thus for $h(t)=0$, we have $\lambda \ge 0$,  if $r(t)> 0$ and $\lambda \le 0$,
if $r(t) < 0$.
These results are well-known for the eigenvalue problem \eqref{eqeq1}-\eqref{eqeq2}
 with integer order $\delta=2$, see \cite{protter}. And here we proved that
 they are valid for any $1 < \delta < 2$. As a simple illustration consider
the eigenvalue problem
\begin{equation}
D^{\delta} u(t)+g(t)u'-u=-\lambda e^t u , \quad t\in (0,1), \; 1 <\delta < 2,
\end{equation}
 with boundary conditions \eqref{eqeq2}.
For $\alpha \ge \frac{1}{\delta-1}$ the eigenvalues of the problem satisfy
$$
\lambda \ge \inf_{t\in [0,1]}\Big(-\frac{-1}{e^t}\Big)
=\inf_{t\in [0,1]}\Big(e^{-t}\Big)=e^{-1}.
$$
We now consider another special case of the linear eigenvalue problem
\eqref{eqeq1}-\eqref{eqeq2} where $g(t)=0, r(t) >0$ and $h(t)<0$. We have
\begin{equation}\label{e222}
D^\delta u + h(t) u=-\lambda r(t) u, \quad t\in (0,1), \; 1 <\delta < 2.
\end{equation}
For $\alpha \ge 1/(\delta-1)$ the eigenvalues of the problem satisfy
$$
\lambda \ge \inf_{t\in [0,1]}\Big(-\frac{h(t)}{r(t)}\Big)>0.
$$
From the above discussion and numerical results in \cite{abbasbandy,odibat,qi}
we believe that the eigenvalues and eigenfunctions of the
 eigenvalue problem \eqref{e222}-\eqref{eqeq2} satisfy the following claim:

\begin{conjecture}
 \begin{itemize}
 \item[(1)] The first eigenfunction $\phi_1$ has  one sign on $[0,1]$.
  That is, either $\phi_1 \ge 0$ or $\phi_1\le 0$ on $[0,1]$.
 \item[(2)] The first eigenvalue $\lambda_1$ increases with $\delta$.
 \end{itemize}
 \end{conjecture}
We leave these open problems for future work and hopefully they will
 open new areas of research for interested researchers. 
It is well-known that the first eigenfunction of the Sturm-Liouville 
eigenvalue problem is important and has various applications.
 We expect the first eigenfunction of the problem \eqref{e222}-\eqref{eqeq2}
 will play the same role. Also, if (2) is true, then we can use the 
eigenvalues of the Sturm-Liouville problem as  upper bounds for the 
ones of fractional order.

\section{Concluding Remarks}
We have studied analytically a class of eigenvalue problems of fractional 
order $1 < \delta < 2$. We have  obtained a new positivity result and used 
it to derive  a sufficient condition 
(H1):$h(t)+\lambda \frac{\partial k}{\partial u} <0$,
 which guarantees  the uniqueness of solutions and ordering of
  any lower and upper solutions for any $\alpha \ge \frac{1}{\delta-1}$. 
For the case where  the nonlinear term $k(t,u)$ in the problem satisfies
 $k(t,0)=0$, analytical upper and lower bounds estimates
of the eigenvalues  are obtained.  
These bounds have  closed forms and can be easily computed.
A sufficient condition (H2) for   the non existence of ordered solution is 
obtained by transforming the problem into equivalent integro-differential equation. 
The method of lower and upper solutions is used to obtain two well-defined 
sequences of lower and upper solutions which converge uniformly to a solution 
of the problem. Under the condition (H1) or (H2) we proved that these lower
 and upper solutions converge to the same limit, which is the unique solution 
of the problem.  We illustrated  these result by considering some 
linear eigenvalue problems. We believe that these analytical results 
are useful in the applications and numerical treatments  and leads to 
better understanding of the problem.  While some results have been established,
 many open problems are still not verified and we leave them for future work.

\subsection*{Acknowledgements}
The Author would like to thank the anonymous reviewers for their valid 
comments and corrections which improved the quality of this article.

\begin{thebibliography}{00}

\bibitem{abbasbandy} S. Abbasbandy and A. Shirzadi;
\emph{Homotopy analysis method for multiple solutions of
 the fractional Sturm-Liouville problems}, 
Numerical Algorithms, \textbf{54}, 4 (2011), 521-532.

\bibitem{agarwal} R. P. Agarwal, N. Benchohra, and S. Hamani;
\emph{boundary-value problems for Fractional Differential Equations}, 
Georgian Mathematical Journal, \textbf{16} (2009), 401-411.

\bibitem{agarwal2} R. P. Agarwal, N. Benchohra, and S. Hamani;
A Survey on existing results for boundary-value problems of nonlinear 
fractional differential equations and inclusions,
Acta Appl. Math, \textbf{109} (2010), 973-1033.

\bibitem{ref} M. Al-Refai, M. Hajji;
Monotone iterative sequences for nonlinear boundary-value problems of fractional
order, Nonlinear Analysis Series A: Theory, Methods and Applications
\textbf{74} (2011),  3531-3539.

\bibitem{alrefai} M. Al-Refai;
\emph{On the fractional derivative at extreme points},
 Electronic Journal of Qualitative Theory of Differential Equations,
 \textbf{55} (2012),  1-5.

\bibitem{atanackovic} T. M. Atanackovic and B. Stankovic;
\emph{Generalized wave equation in nonlocal elasticity},
 Acta Mech. \textbf{208} (2009), 1-10.

\bibitem{bai1} Z. Bai and H. Lu;
\emph{Positive solutions for boundary-value problems of nonlinear fractional
 differential equation}, Journal f Mathematical Analysis and Applications,
\textbf{311,2} (2005), 495-505.

\bibitem{bai2} Z. Bai;
\emph{On positive solutions of a nonlocal fractional
boundary-value problem, Nonlinear Analysis}, \textbf{72} (2010),
916-924.

\bibitem{caputo} M. Caputo;
\emph{Linear models of dissipation whose q is almost frequency independent}, 
Part II Geophys. JR. Astr. Soc., \textbf{13} (1967), 529-539.

\bibitem{furati} K. Furati and N. Tatar;
\emph{An existence result for a nonlocal fractional differential problem}, 
Journal of Fractional Calculus, \textbf{26} (2004), 43-51.

\bibitem{furati2} K.  Furati and M. Kirane;
\emph{Necessary conditions for the existence of global solutions to systems
of fractional differential equations}, 
Fractional Calculus and Applied Analysis \textbf{11} (2008),
281-298.

\bibitem{kilbas} A. A. Kilbas, H. M. Srivastava, and J. J. Trujillo;
\emph{Theory and Applications of Fractional Differential Equations},
North-Holland Mathematics Studies, vol. 204, Elsevier, Amsterdam, 
The Netherlands, 2006.

\bibitem{lak1} V. Lakshmikantham, A. S. Vatsala;
\emph{Basic theory of fractional differential equations},
 Nonlinear Anal. \textbf{69} (2008),  2677-2682.

\bibitem{lak2} V. Lakshmikantham, A. S. Vatsala;
\emph{Theory of fractional differential inequalities
 and applications}, Commun. Appl. Anal. \textbf{11} (2007), 395-402.

\bibitem{lak3} V. Lakshmikantham, A. S. Vatsala;
\emph{General uniqueness and monotone iterative technique for fractional 
differential equations},
Appl. Math. Lett. 2008, 21L,  828-834.

\bibitem{odibat} Z .M. Odibat;
\emph{Computing eigenelements of boundary-value problems with fractional derivatives},
Applied Mathematics and Computation, \textbf{215}(2009), 3017-3028.

\bibitem{pao} C. V. Pao;
\emph{Nonlinear Parabolic and Elliptic Equations}, Plenum Press, New York, 1992.

\bibitem{podlubny} I. Podlubny;
\emph{Fractional Differential Equations, Mathematics in Science and Engineering},
Academic Press, San Diego, Calif, USA, 1993.

\bibitem{protter} M. H. Protter and H. Weinberger;
\emph{Maximum Principles in Differential Equations}, 
Springer-Verlag, New York (1984).


\bibitem{qi} Jiangang Qi and Shaozhu;
\emph{Eigenvalue problems of the model from nonlocal continuum mechanics},
 Journal of Mathematical Physics, \textbf{52} 073516(2011).

\bibitem{shuqin} Shuqin Zhang;
\emph{Existence of solution for a boundary-value problem of fractional order},
Acta Mathematica Scientia, \textbf{26B(2)} (2006), 220-228.

\bibitem{zhang} Shuqin Zhang;
\emph{Positive solutions for boundary-value problems of nonlinear fractional 
differential equations},
Electronic Journal of Differential Equations, Vol. 2006(2006), \textbf{36}, 1�12.

\end{thebibliography}

\end{document}