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

\AtBeginDocument{{\noindent\small
\emph{Electronic Journal of Differential Equations},
Vol. 2010(2010), No. 16, pp. 1--5.\newline
ISSN: 1072-6691. URL: http://ejde.math.txstate.edu or http://ejde.math.unt.edu
\newline ftp ejde.math.txstate.edu}
\thanks{\copyright 2010 Texas State University - San Marcos.}
\vspace{9mm}}

\begin{document}
\title[\hfilneg EJDE-2010/16\hfil Existence of entire positive solutions]
{Existence of entire positive solutions for a class of
semilinear elliptic systems}

\author[Z. Zhang\hfil EJDE-2010/16\hfilneg]
{Zhijun Zhang}

\address{Zhijun Zhang \newline
School of Mathematics and Information Science,
Yantai University,
Yantai, Shandong, 264005,  China}
\email{zhangzj@ytu.edu.cn}

\thanks{Submitted October 22, 2009. Published January 27, 2010.}
\thanks{Supported by grants 10671169 from NNSF of China,
and 2009ZRB01795 from NNSF of \hfill\break\indent Shandong Province}
\subjclass[2000]{35J55, 35J60, 35J65}
 \keywords{Semilinear elliptic systems; entire solutions; existence}

\begin{abstract}
 Under simple conditions on $f_i$ and $g_i$, we show
 the existence of entire positive radial solutions for
 the semilinear elliptic system
 \begin{gather*}
  \Delta u =p(|x|)f_1(v)f_2(u)\\
  \Delta v =q(|x|)g_1(v)g_2(u),
 \end{gather*}
 where $x\in \mathbb{R}^N$, $N\geq 3$, and $p,q$ are continuous
 functions.
\end{abstract}

\maketitle
\numberwithin{equation}{section}
\newtheorem{theorem}{Theorem}[section]
\newtheorem{remark}[theorem]{Remark}

\section{Introduction}

The purpose of this paper is to investigate the existence of entire
positive radial solutions to the  semilinear elliptic
system
\begin{equation}
\begin{gathered}
\Delta u=p(|x|)f_1(v)f_2(u),\quad x \in R^N , \\
\Delta v=q(|x|)g_1(v)g_2(u),\quad x \in R^N,
\end{gathered} \label{e1.1}
\end{equation}
where $N\geq 3$.
We assume that $p,q,f_i,g_i$ ($i=1, 2$) satisfy the
following hypotheses.
\begin{itemize}
\item[(H1)] The functions  $p,q,f_i,g_i:[0,\infty)\to  [0,\infty)$ are
continuous;
\item[(H2)] the functions  $f_i$ and $g_i$ are increasing on $[0,\infty)$.
\end{itemize}
 Denote
\begin{gather*}
P(\infty):=\lim_{r\to \infty}P(r),\quad
P(r)=\int_{0}^{r}t^{1-N}
 \Big(\int_{0}^{t} s^{N-1}p(s) ds\Big)dt,\quad r\geq 0,\\
Q(\infty):=\lim_{r\to \infty}Q(r),\quad
Q(r)=\int_{0}^{r}t^{1-N}
\Big(\int_{0}^{t} s^{N-1}q(s)ds\Big)dt,\quad r\geq 0,\\
F(\infty):=\lim_{r\to \infty}F(r),\quad
F(r)=\int_a^r\frac {ds}{f_1(s)f_2(s)+g_1(s)g_2(s)},\quad  r\geq a>0.
\end{gather*}
We see that $F'(r)=\frac {1}{f_1(r)f_2(r)+g_1(r)g_2(r)}>0$,
for $r>a$ and $F$ has the inverse function $F^{-1}$ on $[a, \infty)$.

This problem arises in many branches of mathematics and physics
and has been discussed by many authors; see, for instance,
 \cite {CR}-\cite{LW1}, \cite {LZZ,PS,WW}  and the references
therein.

When  $f_2=g_1\equiv 1$, $f_1(v)=v^\alpha$, $g_2(u)=u^\beta$,
$0<\alpha\leq \beta$, Lair and Wood \cite {LW1}  considered the
existence and nonexistence of entire positive radial solutions to
 \eqref{e1.1}. Their results were  extended by
C\^{\i}rstea and R\u adulescu \cite{CR},  Wang and Wood \cite{WW},
Ghergu and R\u adulescu \cite {GR},  Peng and
Song \cite{PS},   Ghanmi, M\^{a}agli, R\u{a}dulescu and
Zeddini \cite {GMRZ}, and the authors of this article in \cite {LZZ}.

When  $f_1(v)=v^{\alpha_1}$, $f_2(u)=u^{\alpha_2}$,
$g_1(v)=v^{\beta_1}$, $g_2(u)=u^{\beta_2}$, where $\alpha_1>0$,
$\beta_2>0$,   $\alpha_2>1$ and $\beta_1>1$, Garc\'ia-Meli\'an
and Rossi \cite {GMR}, Garc\'ia-Meli\'an \cite {GM} have
studied  the existence, uniqueness and exact blow-up rate near
the boundary of  positive solutions to system \eqref{e1.1}
on a bounded domain.

In this paper, we give simple conditions on $f_i$ and $g_i$ to show
the existence of entire positive radial solutions to \eqref{e1.1}.
Our main results are as the following.

\begin{theorem} \label{thm1.1}
Under hypotheses {\rm (H1)--(H2)} and
\begin{itemize}
\item[(H3)]   $F(\infty)=\infty$,
\end{itemize}
system  \eqref{e1.1}  has one positive radial solution $(u,v)
\in C^2([0,\infty))$. Moreover,  when $P(\infty)<\infty$ and
$Q(\infty)<\infty$, $u$ and $v$ are bounded;   when
$P(\infty)=\infty =Q(\infty)$,
$\lim _{r\to \infty}u(r)=\lim _{r\to \infty}v(r)=\infty$.
\end{theorem}

\begin{theorem} \label{thm1.2}
Under  hypotheses {\rm (H1)--(H2)} and
\begin{itemize}
\item[(H4)]  $F(\infty)<\infty$;
\item[(H5)]  $P(\infty)<\infty$, $Q(\infty)<\infty$;
\item[(H6)]  there exist $b>a$ and $c>a$ such that
$P(\infty)+Q(\infty)<F(\infty)-F(b+c)$,
\end{itemize}
system \eqref{e1.1} has one
positive radial bounded solution $(u,v) \in C^2([0,\infty))$
satisfying
\begin{gather*}
b +f_1(c)f_2(b)P(r)\leq u(r)\leq F^{-1} \Big (F(b+c)+P(r)+Q(r)\Big ),\quad
 \forall  r\geq 0; \\
c +g_1(c)g_2(b)Q(r)\leq v(r)\leq F^{-1}\Big
(F(b+c)+P(r)+Q(r) \Big),\quad  \forall r \geq 0.
\end{gather*}
\end{theorem}


\begin{remark} \label{rmk1.1} \rm
 From (H1)--(H2), we see that (H3) implies
\begin{equation}
\int_a^\infty\frac {ds}{f_1(s)f_2(s)}
=\int_a^\infty\frac {ds}{g_1(s)g_2(s)}=\infty.\label{e1.2}
\end{equation}
\end{remark}

\begin{remark} \label{rmk1.2} \rm
 When  $f_1(v)=v^{\alpha_1}$, $f_2(u)=u^{\alpha_2}$,
$g_1(v)=v^{\beta_1}$, $ g_2(u)=u^{\beta_2}$, where $\alpha_i$ and
$\beta_i$ are positive constants, we see that (H3)
holds provided $\max\{\alpha_1+\alpha_2$,
$\beta_1+\beta_2\}\leq 1$ and (H4) holds provided
$\alpha_1+\alpha_2>1$ or $\beta_1+\beta_2>1$.
\end{remark}

\begin{remark} \label{rmk1.3} \rm
 By \cite {LW2},  we see that
$P(\infty)=\infty$ if and only if $\int_0^\infty sp(s)ds=\infty$.
\end{remark}


\section{Proof of  Theorems \ref{thm1.1} and \ref{thm1.2}}

Note that radial solutions of  \eqref{e1.1} are solutions of the
ordinary differential equation system
\begin{gather*}
 u''+\frac {N-1}{r}u'=p(r)f_1(v)f_2(u),\\
 v''+\frac {N-1}{r}v'=q(r)g_1(v)g_2(u).
\end{gather*}
Thus solutions of \eqref{e1.1} are simply solutions of
\begin{gather*}
 u(r)=b+\int_{0}^{r}t^{1-N}
 \Big(\int_{0}^{t} s^{N-1}p(s)f_1(v(s))f_2(u(s)) ds\Big)dt,\quad r\geq 0, \\
 v(r)=c+\int_{0}^{r}t^{1-N}
 \Big(\int_{0}^{t}   s^{N-1}q(s)g_1(v(s))g_2(u(s)) ds\Big)dt,\quad r\geq 0.    \\
\end{gather*}
 Let $\{u_{m}\}_{m\geq 0}$
and $\{v_{m}\}_{m\geq 0}$ be the sequences of positive continuous
functions defined on $[0,\infty)$ by
\begin{gather*}
 u_{0}(r)\equiv b, \quad  v_{0}(r)\equiv c,\\
 u_{m+1}(r)=b+\int_{0}^{r} t^{1-N}
 \Big(\int_{0}^{t} s^{N-1}p(s)f_1(v_{m}(s))f_2(u_{m}(s)) ds\Big)dt,\quad
 r\geq 0,\\
 v_{m+1}(r)=c+\int_{0}^{r} t^{1-N}
 \Big(\int_{0}^{t} s^{N-1}q(s)g_1(v_{m}(s))g_2(u_{m}(s)) ds\Big)dt,\quad
  r\geq 0.
\end{gather*}
 Obviously,  for all $ r\geq 0$ and $m\in {\mathbb{N}}$,
$u_{m}(r)\geq b$,  $v_{m}(r)\geq c$ and
$$
v_0\leq v_1,\quad u_0\leq u_1, \quad \forall r\geq 0.
$$
Hypothesis (H2) yields
$$
u_1(r)\leq u_2(r),\quad   v_1(r)\leq v_2(r), \quad \forall r\geq 0.
$$
Continuing this line of reasoning, we obtain that the sequences
$\{u_m\}$ and $\{v_m\}$ are increasing on $[0, \infty)$.
Moreover,  we obtain by (H1) and (H2) that, for each $r>0$,
\begin{align*}
u_{m+1}'(r)
&=r^{1-N} \int_{0}^{r} s^{N-1}p(s)f_1(v_{m}(s))f_2(u_{m}(s)) ds\\
&\leq f_1(v_{m}(r))f_2(u_{m}(r))P'(r)\\
&\leq  f_1\big(v_{m+1}(r)+u_{m+1}(r)\big)f_2
  \big(v_{m+1}(r)+u_{m+1}(r)\big)P'(r)\\
&\leq  \Big[ f_1\big(v_{m+1}(r)+u_{m+1}(r)\big)f_2
  \big(v_{m+1}(r)+u_{m+1}(r)\big)\\
&\quad +g_1\big(v_{m+1}(r)+u_{m+1}(r)\big)g_2
 \big(v_{m+1}(r)+u_{m+1}(r)\big)\Big]P'(r)\,,
\end{align*}
\begin{align*}
v_{m+1}'(r)
&=r^{1-N} \int_{0}^{r} s^{N-1}q(s)g_1(v_{m}(s))g_2(u_{m}(s)) ds\\
&\leq g_1\big(v_{m}(r))g_2(u_{m}(r)\big)Q'(r)\\
&\leq g_1\big(v_{m+1}(r)+u_{m+1}(r)\big)g_2
 \big(v_{m+1}(r)+u_{m+1}(r)\big)Q'(r)\\
&\leq \Big[f_1\big(v_{m+1}(r)+u_{m+1}(r)\big)f_2
 \big(v_{m+1}(r)+u_{m+1}(r)\big)\\
&\quad +g_1\big(v_{m+1}(r)+u_{m+1}(r)\big)
 g_2\big(v_{m+1}(r)+u_{m+1}(r)\big)\Big]Q'(r)
\end{align*}
and
\[
\int_{b+c}^{v_{m+1}(r)+u_{m+1}(r)}\frac {d\tau}{f_1(\tau)
f_2(\tau)+g_1(\tau) g_2(\tau)} \leq  Q(r)+P(r).
\]
Consequently,
\begin{equation}
F\big(u_m(r)+v_m(r)\big)-F(b+c)\leq P(r)+Q(r), \quad \forall r\geq 0.
\label{e2.1}
\end{equation}
Since $F^{-1}$ is  increasing on $[0, \infty)$,  we have
\begin{equation}
u_m(r)+v_m(r)\leq F^{-1}\big (F(b+c)+P(r)+Q(r)\big),\quad \forall
r\geq 0. \label{e2.2}
\end{equation}
(i)  When (H3) holds,  we see that
\begin{equation}
F^{-1}(\infty)=\infty.\label{e2.3}
\end{equation}
It follows  that  the sequences
$\{u_m\}$ and $\{v_m\}$ are bounded  and  equicontinuous on
$[0,c_0]$ for arbitrary $c_0>0$. It follows by Arzela-Ascoli theorem
that $\{u_m\}$ and $\{v_m\}$ have subsequences converging uniformly
to $u$ and $v$ on $[0, c_0]$. By the arbitrariness of $c_0>0$, we
see that $(u, v)$ are positive entire solutions of  \eqref{e1.1}.
Moreover,  when $P(\infty)<\infty$ and $Q(\infty)<\infty$, we see by
\eqref{e2.2} that
$$
u(r)+v(r)\leq F^{-1}\big(F(b+c)+P(\infty)+Q(\infty)\big),\quad
\forall   r\geq 0;
$$
and,when $P(\infty)=\infty =Q(\infty)$, by (H2) and the monotones of
$\{u_m\}$ and $\{v_m\}$,
$$
u(r)\geq b +f_1(c)f_2(b)P(r),\quad
v(r)\geq c +g_1(c)g_2(b)Q(r),\quad \forall r\geq0.
$$
Thus $\lim _{r\to \infty} u(r)=\lim_{r\to \infty}v(r)=\infty$.

\noindent(ii)  When (H4)--(H6) hold,  we see  by
\eqref{e2.1} that
\begin{equation}
F(u_m(r)+v_m(r))\leq F(b+c)+P(\infty)+Q(\infty)<F(\infty)<
\infty. \label{e2.4}
\end{equation}
Since $F^{-1}$ is strictly increasing on $[0,\infty)$,  we have
\begin{equation}
u_m(r)+v_m(r)\leq F^{-1}\big (F(b+c)+P(\infty)+Q(\infty)\big)<\infty,\quad
 \forall r\geq 0. \label{e2.5}
\end{equation}
The last part of the proof follows from (i).
Thus the proof is complete.


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\end{thebibliography}

\end{document}