- Research Article
- Open access
- Published:
Infinitely Many Solutions of Strongly Indefinite Semilinear Elliptic Systems
Boundary Value Problems volume 2009, Article number: 865408 (2009)
Abstract
We proved a multiplicity result for strongly indefinite semilinear elliptic systems 
in 
, 
in 
where 
and 
are positive numbers which are in the range we shall specify later.
1. Introduction
In this paper, we shall study the existence of multiple solutions of the semilinear elliptic systems
where 
and 
are positive numbers which are in the range we shall specify later. Let us consider that the exponents 
, 
are below the critical hyperbola
so one of 
and 
could be larger than 
; for that matter, the quadratic part of the energy functional
has to be redefined, and we then need fractional Sobolev spaces.
Hence the energy functional 
is strongly indefinite, and we shall use the generalized critical point theorem of Benci [1] in a version due to Heinz [2] to find critical points of 
. And there is a lack of compactness due to the fact that we are working in 
.
In [3], Yang shows that under some assumptions on the functions 
and 
there exist infinitely many solutions of the semilinear elliptic systems
We shall propose herein a result similar to [3] for problem (1.1).
2. Abstract Framework and Fractional Sobolev Spaces
We recall some abstract results developed in [4] or [5].
We shall work with space 
, which are obtained as the domains of fractional powers of the operator
Namely, 
for 
, and the corresponding operator is denoted by 
. The spaces 
, the usual fractional Sobolev space 
, are Hilbert spaces with inner product
and associates norm
It is known that 
is an isomorphism, and so we denote by 
the inverse of 
.
Now let 
, 
with 
. We define the Hilbert space 
and the bilinear form 
by the formula
Using the Cauchy-Schwarz inequality, then it is easy to see that 
is continuous and symmetric. Hence 
induces a self-adjoint bounded linear operator 
such that
Here and in what follows 
denotes the inner product in 
induced by 
and 
on the product space 
in the usual way. It is easy to see that
We can then prove that 
has two eigenvalues 
and 
, whose corresponding eigenspaces are
which give a natural splitting 
. The spaces 
and 
are orthogonal with respect to the bilinear form 
, that is,
We can also define the quadratic form 
associated to 
and 
as
for all 
. It follows then that
where 
, 
, 
. If 
, that is, 
, we have
Similarly
for 
.
If 
where 
is a number satisfying the condition
and 
, it follows by (2.13) that 
and by H
lder inequalities that
In the sequel 
denotes the norm in 
, and we denote by 
the weighted function spaces with the norm defined on 
by 
. According to the properties of interpolation space, we have the following embedding theorem.
Theorem 2.1.
Let 
. one defines the operator 
as follows: for 
, 
,
Then the inclusion of 
into 
is compact if 
.
Proof.
Observe that, by H
lder's inequality and (2.14), we have
where 
; hence 
is well defined.
Then we will claim that 
is compact. Since 
, for any 
, there exists 
, such that 
. Now, suppose 
weakly in 
. We estimate
letting
we have
so that by H
lder's inequality, we observe that, for any 
, we can choose a 
so that the integral over (
) is smaller than 
for all 
, while for this fixed 
, by strong convergence of 
to 
in 
on any bounded region, the integral over (
) is smaller than 
for 
large enough. We thus have proved that 
strongly in 
; that is, the inclusion of 
into 
is compact if 
.
3. Main Theorem
We consider below the problem of finding multiple solutions of the semilinear elliptic systems
Now if we choose 
, 
, 
, such that
and we assume that
(H) 
, 
and 
and 
are positive numbers such that
We set
and we let
so that, under assumption (H), Theorem 2.1 holds, respectively, with 
and 
, and 
and 
; that is, the inclusion of 
into 
and the inclusion of 
into 
are compact.
If 
, we let
denote the energy of 
. It is well known that under assumption (H) the energy functional 
is well defined and continuously differentiable on 
, and for all 
we have
and it is also well known that the critical points of 
are weak solutions of problem (3.1). The main theorem is the following.
Theorem 3.1.
Under assumption (H), problem (3.1) possesses infinitely many solutions 
.
Since the functional 
are strongly indefinite, a modified multiplicity critical points theorem Heinz [2] which is the generalized critical point theorem of Benci [1] will be used. For completeness, we state the result from here.
Theorem 3.2.
(see [2]) Let 
be a real Hilbert space, and let 
be a functional with the following properties:
(i) 
has the form
where 
is an invertible bounded self-adjoint linear operator in 
and where 
is such that 
and the gradient 
is a compact operator;
(ii) 
is even, that is 
;
(iii) 
satisfies the Palais-Smale condition. Furthermore, let
be an orthogonal splitting into 
-invariant subspaces 
, 
such that 
. Then,
-
(a)
suppose that there is an
-dimensional linear subspace 
of 
(
) such that for the spaces 
, 
one has
-dimensional linear subspace 
of 
(
) such that for the spaces 
, 
one has(iv) 
such that 
, 
;
(v) 
such that 
.Then there exist at least 
pairs 
of critical points of 
such that 
(
);
-
(b)
a similar result holds when
, and one takes 
, 
.
, and one takes 
, 
.It is known from Section 2 that the operator 
induced by the bilinear form 
is an invertible bounded self-adjoint linear operator satisfying 
. We shall need some finite dimensional subspace of 
. Let 
, 
, 
,
, be a complete orthogonal system in 
. Let 
denote the finite dimensional subspaces of 
generated by 
, 
, 
,
,
. Since 
and 
are isomorphisms, we know that 
, 
, 
,
, is a complete orthogonal system in 
. Let 
denote the finite dimensional subspaces of 
generated by 
, 
, 
,
,
. For each 
, we introduce the following subspaces of 
and 
Lemma 3.3.
The functional 
defined in (3.6) satisfies conditions (ii), (iv), and (v) of Theorem 3.2.
Proof.
Condition (ii) is an immediate consequence of the definition of 
. For condition (iv), by (2.11) and Theorem 2.1, for 
,
and since 
, 
, we conclude that 
for 
with 
small.
Next, let us prove condition (v). Let 
be fixed, let 
, and write 
and 
. We have
Let 
and 
. Then we have 
and 
. Furthermore, we may write 
, where 
is orthogonal to 
in 
. We also have 
, where 
is orthogonal to 
in 
. It is easy to see that either 
or 
is positive. Suppose 
. Then we have
Using the fact that the norms in 
are equivalent we obtain
with constant 
independent of 
. So from (3.13) and (2.11) we obtain
The same arguments can be applied if 
. So the result follows from (3.16).
A sequence 
is said to be the Palais-Smale sequence for 
(PS)-sequence for short) if 
uniformly in 
and 
in 
. We say that 
satisfies the Palais-Smale condition (PS)-condition for short) if every (PS)-sequence of 
is relatively compact in 
.
Lemma 3.4.
Under assumption (H), the functional 
satisfies the (PS)-condition.
Proof.
We first prove the boundedness of (PS)-sequences of 
. Let 
be a (PS)-sequence of 
such that
Taking 
in (3.18), it follows from (3.17), (3.18), that
Next, we estimate 
and 
. From (3.18) with 
, we have
for all 
. Using H
lder's inequality and by (3.20), we obtain
for all 
, which implies that
Similarly, we prove that
Adding (3.22) and (3.23) we conclude that
Using this estimate in (3.19), we get
Since 
and 
, we conclude that both 
and 
are bounded, and consequently 
and 
are also bounded in terms of (3.24).
Finally, we show that 
contains a strongly convergent subsequence. It follows from 
and 
which are bounded and Theorem 2.1 that 
contains a subsequence, denoted again by 
, such that
It follows from (3.18) that
Therefore,
and by Theorem 2.1, we conclude that 
strongly in 
and 
strongly in 
.
Proof of Theorem 3.1.
Applying Lemmas 3.3 and 3.4 and Theorem 3.2, we can obtain the conclusion of Theorem 3.1.
References
Benci V: On critical point theory for indefinite functionals in the presence of symmetries. Transactions of the American Mathematical Society 1982, 274(2):533-572. 10.1090/S0002-9947-1982-0675067-X
Heinz H-P: Existence and gap-bifurcation of multiple solutions to certain nonlinear eigenvalue problems. Nonlinear Analysis: Theory, Methods & Applications 1993, 21(6):457-484. 10.1016/0362-546X(93)90128-F
Yang J: Multiple solutions of semilinear elliptic systems. Commentationes Mathematicae Universitatis Carolinae 1998, 39(2):257-268.
de Figueiredo DG, Felmer PL: On superquadratic elliptic systems. Transactions of the American Mathematical Society 1994, 343(1):99-116. 10.2307/2154523
de Figueiredo DG, Yang J: Decay, symmetry and existence of solutions of semilinear elliptic systems. Nonlinear Analysis: Theory, Methods & Applications 1998, 33(3):211-234. 10.1016/S0362-546X(97)00548-8
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
Open Access This article is distributed under the terms of the Creative Commons Attribution 2.0 International License (https://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
About this article
Cite this article
Chen, KJ. Infinitely Many Solutions of Strongly Indefinite Semilinear Elliptic Systems. Bound Value Probl 2009, 865408 (2009). https://doi.org/10.1155/2009/865408
Received:
Accepted:
Published:
DOI: https://doi.org/10.1155/2009/865408