Ground States for a Class of Nonlinear Schrodinger-Poisson Systems with Positive Potential ()
1. Introduction
In this paper, we consider the following nonlinear Schrodinger-Poisson systems
(1.1)
where
,
;
, 
and 
are positive potentials defined in
.
In recent years, such systems have been paid great attention by many authors concerning existence, non- existence, multiplicity and qualitative behavior. The systems are to describe the interaction of nonlinear Schrodinger field with an electromagnetic field. When
, 
, 
, the existence of non- trivial solution for the problem (1.1) was proved as 
in [1] , and non-existence result for 
or 
was proved in [2] . When
, 
, ![]()
, using critical point theory, Ruiz [3] obtained some multiplicity results for![]()
, and existence results for![]()
. Later, Ambrosetti and Ruiz [4] , and Ambrosetti [5] generalized some existence results of Ruiz [3] , and obtained the existence of infinitely solutions for the problem (1.1).
In particular, Sanchel and Soler [6] considered the following Schrodinger-Poisson-Slater systems
![]()
(1.2)
where![]()
. The problem (1.2) was introduced as the model of the Hartree-Foch theory for a one-compo- nent plasma. The solution is obtained by using the minimization argument and ![]()
as a Lagrange multiplier. However, it is not known if the solution for the problem (1.2) is radial. Mugani [7] considered the following generalized Schrodinger-Poisson systems
![]()
(1.3)
where![]()
, ![]()
and![]()
, and proved the existence of radially symmetric solitary waves for the problem (1.3).
In this paper, without requiring any symmetry assumptions on![]()
, ![]()
and![]()
, we obtain the existence of positive radial ground state solution for the problem (1.1). In particular, the positive potential ![]()
implies that we are dealing with systems of particles having positive mass. It is interesting in physical applications.
The paper is organized as following. In Section 2, we collect some results and state our main result. In Section 3, we prove some lemmas and consider the problem (1.1) at infinity. Section 4 is devoted to our main theorem.
2. Preliminaries and Main Results
Let![]()
, ![]()
denotes a Lebesgue space, the norm in ![]()
is![]()
, ![]()
is the completion of ![]()
with respect to the norm
![]()
![]()
be the usual Sobolev space with the usual norm
![]()
.
Assume that the potential ![]()
satisfies
H1)![]()
, ![]()
,![]()
.
Let ![]()
be the Hilbert subspace of ![]()
such that
![]()
(2.1)
Then![]()
, ![]()
with the corresponding embeddings being continuous (see [8] ). Furthermore, assume the potential ![]()
satisfies
H2)![]()
, ![]()
,![]()
.
It is easy to reduce the problem (1.1) to a single equation with a non-local term. Indeed, for every![]()
, we have
![]()
(2.2)
Since![]()
, ![]()
and (2.1), by the Lax-Milgram theorem, there exists a
unique ![]()
such that
![]()
(2.3)
It follows that ![]()
satisfies the Poisson equation
![]()
and there holds
![]()
Because![]()
, we have ![]()
when![]()
, and![]()
, ![]()
is positive constant.
Substituting ![]()
in to the problem (1.1), we are lead to the equation with a non-local term
![]()
. (2.4)
In the following, we collect some properties of the functional![]()
, which are useful to study our problem.
Lemma 2.1. [9] For any![]()
, we have
1) ![]()
is continuous, and maps bounded sets into bounded sets;
2) if ![]()
weakly in![]()
, then ![]()
weakly in![]()
;
3) ![]()
for all ![]()
Now, we state our main theorem in this paper.
Theorem 2.2. Assume that![]()
, ![]()
, the potential ![]()
satisfies condition H1), the potential ![]()
satisfies condition H3) and![]()
, the potential ![]()
satisfies
H3)![]()
, ![]()
, ![]()
and![]()
, ![]()
on positive measure. Then there exists a positive radial ground state solution for the problem (1.1).
Remark 2.3. If![]()
, ![]()
, ![]()
and ![]()
are positive potentials defined in![]()
, and![]()
, ![]()
be a solution for the problem (1.1). Then![]()
, Indeed, we have
![]()
Since![]()
, this implies![]()
. By Lemma 2.1, we have![]()
.
3. Some Lemmas and the Problem (1.1) at Infinity
Now, we consider the functional ![]()
given by
![]()
Since ![]()
satisfies condition H2), by (2.2), the Holder inequality and Sobolev inequality, we have
![]()
, (3.2)
where ![]()
and![]()
. Since the potential ![]()
satisfies condition Q,
![]()
, we have
![]()
By Sobolev inequality, we obtain that
![]()
(3.3)
Combining (3.2) and (3.3), we obtain that the functional ![]()
is a well defined ![]()
functional, and if ![]()
is critical point of it, then the pair ![]()
is a weak solution of the problem (1.1).
Now, we define the Nehari manifold ([10] ) of the functional ![]()
![]()
,
where
![]()
Hence, we have
![]()
(3.4)
Lemma 3.1. 1) For any![]()
, ![]()
, there exists a unique ![]()
such that![]()
. Moreover, we have ![]()
2) ![]()
is bounded from below on ![]()
by a positive solution.
Proof. 1) Taking any ![]()
and![]()
, we obtain that there exists a unique ![]()
such
that![]()
. Indeed, we define the function![]()
. We note that ![]()
if only if![]()
. Since ![]()
is equivalent to
![]()
.
By![]()
, ![]()
and![]()
, we have
![]()
.
By![]()
, ![]()
, the equation ![]()
has a unique ![]()
and the corresponding point ![]()
and![]()
.
2) Let![]()
, by (3.4) and![]()
, we have
![]()
By the definition of Nehari manifold ![]()
of the functional![]()
, we obtain that
![]()
is a critical point of ![]()
if and only if ![]()
is a critical point of ![]()
constrained on ![]()
(3.5)
Now, we set
![]()
By 2) of Lemma 3.1, we have ![]()
Since![]()
, ![]()
, ![]()
, we consider the problem (1.1) at infinity
![]()
(3.6)
Similar to (2.2), we obtain that there exists a unique ![]()
such that
![]()
.
It follows that ![]()
satisfies the Poisson equation
![]()
(3.7)
Hence substituting ![]()
into the first equation of (3.6) we have to study the equivalent problem
![]()
(3.8)
The weak solution of the problem (3.8) is the critical point of the functional
![]()
where ![]()
is endowed with the norm
![]()
Define the Nehari manifold of the functional ![]()
![]()
,
where
![]()
and
![]()
The Nehari manifold ![]()
has properties similar to those of ![]()
Lemma 3.2. The problem (3.8) has a positive radial ground state solution ![]()
such that
![]()
For the proof of Lemma 3.2, we make use of Schwarz symmetric method. We begin by recalling some basic properties.
Let ![]()
such that![]()
, then there is a unique nonnegative function![]()
, called the Schwarz symmetric of![]()
, such that it depends only on![]()
, whose level sets
![]()
.
We consider the following Poisson equation
![]()
From Theorem 1 of [11] , we have
![]()
.
Hence, let![]()
, ![]()
and![]()
, ![]()
, we have
![]()
. (3.9)
The Proof of Lemma 3.2. Let ![]()
be such that ![]()
Let ![]()
such that ![]()
then we have
![]()
,
and
![]()
.
Hence, we obtain that
![]()
. (3.10)
Since ![]()
and![]()
, (3.10) implies that![]()
. Therefore, we can assume that![]()
.
On the other hand, let ![]()
be the Schwartz symmetric function associated to![]()
, then we have
![]()
(3.11)
Let ![]()
be such that![]()
, and![]()
, by (3.9) and (3.11), we have
![]()
This implies that![]()
. Therefore, we have![]()
, and we can suppose that ![]()
is radial
in![]()
. Since ![]()
is compactly embedded into ![]()
for![]()
, we obtain that ![]()
is achieved at some ![]()
which is positive and radial. Therefore, Lemma 3.2 is proved.
4. The Proof of Main Theorem
In this section, we prove Theorem 2.2. Firstly, we consider a compactness result and obtain the behavior of the (PS) sequence of the functional![]()
.
Lemma 4.1. Let ![]()
be a (PS)d sequence of the functional ![]()
constrained on![]()
, that is
![]()
(4.1)
Then there exists a solution ![]()
of the problem (2.4), a number![]()
, ![]()
functions ![]()
of ![]()
and ![]()
sequences of points![]()
, ![]()
such that
1)![]()
, ![]()
, if![]()
,![]()
;
2)![]()
;
3)![]()
;
4) ![]()
are non-trivial weak solution of the problem (3.8).
Proof. The proof is similar to that of Lemma
4.1 in
[9] .
By Lemma 4.1, taking into account that ![]()
for all ![]()
and![]()
, we obtain that ![]()
and ![]()
in ![]()
(strongly), i.e. ![]()
is relatively compact for all![]()
. Hence we only need to prove that the energy of a solution of the problem (2.4) cannot overcome the energy of a ground state solution of the problem (3.8).
The proof of Theorem 2.2. By Lemma 4.1, we only prove that![]()
. Indeed, let ![]()
such that![]()
, and let ![]()
such that![]()
. Since![]()
, ![]()
and![]()
, we have
![]()
(4.2)
Since ![]()
and![]()
, we have
![]()
Therefore, we have
![]()
By![]()
, we have![]()
. If![]()
, we have ![]()
and![]()
. Hence, by![]()
, we have
![]()
(4.3)
and by![]()
, we have
![]()
. (4.4)
Combining (4.3) and (4.4), we have
![]()
Since![]()
, ![]()
, ![]()
, and ![]()
on a positive measure, we have
![]()
which is not identically zero, and is contradiction. Hence, we have![]()
. By (4.2), we have
![]()
Then there exists a positive radial ground state solution for the problem (1.1).
Acknowledgements
This research is supported by Shanghai Natural Science Foundation Project (No. 15ZR1429500), Shanghai Leading Academic Discipline Project (No. XTKX2012) and National Project Cultivate Foundation of USST (No. 13XGM05).
NOTES
*Corresponding author.