Abstract
In this paper, we are concerned with the existence of least energy sign-changing solutions for the following fractional Kirchhoff problem with logarithmic and critical nonlinearity:
where \(N >sp\) with \(s \in (0, 1)\), \(p>1\), and
\(p_s^*=Np/(N-ps)\) is the fractional critical Sobolev exponent, \(\Omega \subset {\mathbb {R}}^N\) \((N\ge 3)\) is a bounded domain with Lipschitz boundary and \(\lambda \) is a positive parameter. By using constraint variational methods, topological degree theory and quantitative deformation arguments, we prove that the above problem has one least energy sign-changing solution \(u_b\). Moreover, for any \(\lambda > 0\), we show that the energy of \(u_b\) is strictly larger than two times the ground state energy. Finally, we consider b as a parameter and study the convergence property of the least energy sign-changing solution as \(b \rightarrow 0\).
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1 Introduction
In this paper, we are interested in the existence, energy estimates and the convergence property of the least energy sign-changing solution for the following fractional Kirchhoff problems with logarithmic and critical nonlinearity:
where \(N >sp\) with \(s \in (0, 1)\), \(p>1\), and
\(p_s^*=Np/(N-ps)\) is the fractional critical Sobolev exponent, \(\Omega \subset {\mathbb {R}}^N\) \((N\ge 3)\) is a bounded domain with Lipshcitz boundary and \(\lambda \) is a positive parameter. We denote by \((-\Delta )^s_p\) the fractional p-Laplace operator which, up to a normalization constant, is defined as
for all \(\varphi \in C_0^\infty ({\mathbb {R}}^N)\). Henceforward, \(B_\varepsilon (x)\) denotes the open ball of \({\mathbb {R}}^N\) centered at \(x\in {\mathbb {R}}^N\) and radius \(\varepsilon >0\).
One of the classical topics in the qualitative analysis of PDEs is the study of existence and multiplicity properties of solutions for both the Kirchhoff problems and the fractional Kirchhoff problems under various hypotheses on the nonlinearity. In the recent past there is a vast literature concerning the existence and multiplicity of solutions for the following Dirichlet problem of Kirchhoff type
Problem (1.2) is a generalization of a model introduced by Kirchhoff [24]. More precisely, Kirchhoff proposed a model given by the equation
where \(\rho \), \(\rho _0\), h, E, L are constants. This nonlocal model extends the classical D’Alembert’s wave equation, by considering the effects of the changes in the length of the strings during the vibrations. Since Lions [29] introduced an abstract framework to Kirchhoff-type equations, the solvability of these nonlocal problems has been well studied in the general dimension by various authors. We refer to D’Ancona and Shibata [13] and D’Ancona and Spagnolo [14] for the global solvability of various classes of Kirchhoff-type problems. We also refer to Carrier [9, 10] who used a more rigorous method to model transverse vibration via the coupled governing equation of planar vibration in order to recover the nonlinear integro partial-differential equation, in which a more general Kirchhoff function was considered. In addition, the nonlocal Kirchhoff problems of parabolic type can model several biological systems, such as population density, see for example Ghergu and Rădulescu [21]. For more details on mathematical theories and its applications of Kirchhoff-type problems, we refer the readers to [4, 14, 23, 26, 27, 41].
Problem (1.2) is a nonlocal problem because the term \(b\int _{\Omega }|\nabla u|^2dx\Delta u\) appears in the left-hand side of the equation, which results that (1.2) is not a pointwise identity. Moreover, the energy functional associated to (1.2) has different properties with respect to the local case corresponding to \(b = 0\), hence several mathematical difficulties are brought naturally out in the study of the nonlocal problems \((b \ne 0)\) by means of variational methods. Recently, Fiscella and Valdinoci [19] proposed a steady-state Kirchhoff model involving the fractional Laplacian by taking into account the nonlocal aspect of the tension arising from nonlocal measurements of the fractional length of the string, see [19, Appendix A] for more details. Fractional Kirchhoff-type Laplacian problems have been studied by many authors, refer [2, 3, 20, 28, 34, 36, 37, 48, 49, 51]. Here we can refer the recent monograph about nonlocal fractional problems [35]. We note that the results dealing with the problem (1.2) with critical nonlinearity are relatively scarce. The main difficulty in the study of these problems is due to the lack of compactness caused by the presence of the critical Sobolev exponent.
Recently, most of the literature deals with fractional Laplacian problems with power type nonlinearities, there are a few papers that deal with the existence and multiplicity of solutions for fractional problems involving logarithmic nonlinearity. In [15], d’Avenia et al. considered the following fractional logarithmic Schorödinger equation
where \(\omega >0\). By employing the fractional logarithmic Sobolev inequality, [15] obtained the existence of infinitely many solutions. Moreover, the regularity of solutions was also discussed in [15]. In [42], Truong studied the following problem fractional p-Laplacian equations with logarithmic nonlinearity
where a is a sign-changing function. Under some assumptions on V, a and \(\lambda \), [42] obtained two nontrivial solutions by using Nehari manifold approach. Very recently, Xiang, Hu and Yang in [47] considered the following Kirchhoff problems with combined nonlinearity of logarithmic and power type
where \(s\in (0,1)\), \(1<p<N/s\), \(\Omega \) is a bounded domain in \({\mathbb {R}}^N\) with Lipschitz boundary, \(M([u]^p_{s,p})=[u]^{(\theta -1)p}_{s,p}\) with \(\theta \ge 1\), and h is a sign-changing function. When \(\lambda \) is sufficiently small, [47] obtained two nonnegative local least energy solutions by using Nehari manifold approach.
On the other hand, the existence of sign-changing solution of nonlinear elliptic PDEs with power nonlinearities has been studied extensively for the p-Laplacian operator as well as the fractional p-Laplacian operator. We refer the reader to see [5, 6, 11, 12, 30, 44] and the references therein. Consider the nonlocal problem
For \(p = 2\), the authors in [11], have studied the problem (1.4), where the fractional Laplacian operator is defined through spectral decomposition to obtain the sign-changing solution. The method of harmonic extension was introduced by Caffarelli and Silvestre [8] to transform the nonlocal problem in \(\Omega \) to a local problem in the half cylinder \(\Omega \times (0, \infty )\), by using an equivalent definition of the fraction Laplacian operator [7]. For \(p \in (1, \infty )\), the problem studied by Chang et al. [12], where the authors have guaranteed the existence of a sign-changing solutions by using Nehari manifold method.
Recently, many authors pay their attention to find sign-changing solutions to problem (1.2) or similar Kirchhoff-type equations, and indeed, some interesting results were obtained. For example, Zhang and Perera [50] and Mao and Zhang [32] used the method of invariant sets of descent flow to obtain the existence of a sign-changing solution of problem (1.2). In [17], Figueiredo and Nascimento considered the following Kirchhoff equation of the type:
where \(\Omega \) is a bounded domain in \({\mathbb {R}}^3\), M is a general \(C^1\) class function, and g is a superlinear \(C^1\) class function with subcritical growth. By using the minimization argument and a quantitative deformation lemma, the existence of a sign-changing solution for this Kirchhoff equation was obtained. In unbounded domains, Figueiredo and Santos Júnior [18] studied a class of nonlocal Schrödinger–Kirchhof problems involving only continuous functions. Using a minimization argument and a quantitative deformation lemma, they obtained a least energy sign-changing solution to Schrödinger–Kirchhof problems. Moreover, when the problem presents symmetry, the authors showed that it has infinitely many nontrivial solutions.
It is noted that combining constraint variational methods and quantitative deformation lemma, Shuai [38] proved that problem (1.2) has one least energy sign-changing solution \(u_b\) and the energy of \(u_b\) strictly larger than the ground state energy. Moreover, the author investigated the asymptotic behavior of \(u_b\) as the parameter \(b\searrow 0\). Later, under some more weak assumptions on g (especially, Nehari type monotonicity condition been removed), with the aid of some new analytical skills and Non-Nehari manifold method, Tang and Cheng [40] improved and generalized some results obtained in [38].
In [16], Deng, Peng, and Shuai studied the following Kirchhoff problem:
The authors obtained the existence of radial sign-changing solutions with prescribed numbers of nodal domains for Kirchhoff problem (1.6) in \(H^1_r ({\mathbb {R}}^3)\), the subspace of radial functions of \(H^1({\mathbb {R}}^3)\) by using a Nehari manifold and gluing solution pieces together, when \(V(x)= V(|x|)\), \(f(x, u)= f(|x|, u)\) and satisfies some conditions. Precisely, they proved the existence of a sign-changing solution, which changes signs exactly k times for any \(k \in {\mathbb {N}}\). Moreover, they investigated the energy property and the asymptotic behavior of the sign-changing solution. By using a combination of the invariant set method and the Ljusternik–Schnirelman type minimax method, Sun et al. [39] obtained infinitely many sign-changing solutions for Kirchhoff problem (1.6) when \(f(x, u) = f(u)\) and f is odd in u. It is worth noticing that, in [39], the nonlinear term may not be 4-superlinear at infinity; in particular, it includes the power-type nonlinearity \(|u|^{p-2}u\) with \(p \in (2, 4]\). In [43], the authors obtained the existence of least energy sign-changing solutions of Kirchhoff-type equation with critical growth by using the constraint variational method and the quantitative deformation lemma. For more results on sign-changing solutions for Kirchhoff-type equations, we refer the reader to [16, 25, 31] and the references therein.
2 Abstract setting and main results
To the best of our knowledge, there are no results concerning the existence of sign-changing solutions for fractional Kirchhoff problems with logarithmic and critical nonlinearity. Hence, a natural question is whether or not there exist nodal solutions of problem (1.1)? The goal of the present paper is to develop a thorough qualitative analysis in this direction.
We first recall some preliminary results on the fractional Sobolev space \(W^{s,p}_0(\Omega )\) with respect to the norm \( \Vert u\Vert = [u]_{s,p}\). We then have that \(W^{s,p}_0(\Omega )\) is continuously and compactly embedded into the Lebesgue space \(L^r(\Omega )\) endowed the norm \(|u|_r=\left( \int _\Omega |u|^r\,dx\right) ^\frac{1}{r}\), \(p<r<p_s^{*}\). Denote by \(S_r\) the best constant for this embedding, that is,
In particular, if S is the the best constant for the embedding \(W^{s,p}_0(\Omega ) \hookrightarrow L^{p_s^{*}} (\Omega )\), then it is defined by
For the weak solution, we mean the one satisfying the given definition.
Definition 2.1
We say that \(u\in W^{s,p}_0(\Omega )\) is a (weak) solution of problem (1.1) if
where
for any \(v\in W^{s,p}_0(\Omega )\).
The corresponding energy functional \(I_b^{\lambda } : W^{s,p}_0(\Omega ) \rightarrow {\mathbb {R}}\) to problem (1.1) is defined by
It is easy to see that \(I_b^{\lambda }\) belongs to \(C^1(W^{s,p}_0(\Omega ), {\mathbb {R}})\) and the critical points of \(I_b^{\lambda }\) are the solutions of (1.1). Furthermore, if we write
for \(u \in W^{s,p}_0(\Omega )\), then every solution \(u \in W^{s,p}_0(\Omega )\) of problem (1.1) with the property that \(u^\pm \ne 0\) is a sign-changing solution of problem (1.1).
It is noticed that if \(u^\pm \not \equiv 0\)
Our goal in this paper is then to seek the least energy sign-changing solutions of problem (1.1). As we know, there are some very interesting studies, which studied the existence and multiplicity of sign-changing solutions for the following problem:
where \(\Omega \) is an open subset of \({\mathbb {R}}^N\). However, these methods of seeking sign-changing solutions heavily rely on the following decompositions:
where J is the energy functional of (2.4) given by
However, if \(b>0\), the energy functional \(I_b^{\lambda }\) does not possess the same decompositions as (2.7) and (2.8). In fact, a straightforward computation yields that
for \(u^\pm \ne 0\). Therefore, the method to obtain sign-changing solutions for the local problem (2.6) do not seem applicable to problem (1.1). In this paper, we follow the approach in [5] by defining the following constrained set
and considering a minimization problem of \(I_b^{\lambda }\) on \({\mathcal {M}}_b^{\lambda }\). Indeed, by using the parametric method and implicit theorem, Shuai [38] proved \({\mathcal {M}}_b^{\lambda } \ne \emptyset \) in the absence of the nonlocal term. However, the nonlocal term in problem (1.1), consisting of the biharmonic operator and the nonlocal term will cause some difficulties. Roughly speaking, compared to the general Kirchhoff type problem (1.2), decompositions (2.7) and (2.8) corresponding to \(I_b^{\lambda }\) are much more complicated. This results in some technical difficulties during the proof of the nonempty of \({\mathcal {M}}_b^{\lambda }\). Moreover, we find that the parametric method and implicit theorem are not applicable for problem (1.1) due to the complexity of the nonlocal term there. Therefore, our proof takes a different route which is inspired by [1], namely, we make use of a modified Miranda’s theorem (see [33]). We are also able to prove that the minimizer of the constrained problem is also a sign-changing solution via the quantitative deformation lemma and degree theory. We can now present our first main result.
Theorem 2.1
There exists \(\lambda ^{*} > 0\) such that for all \(\lambda \ge \lambda ^{*}\), problem (1.1) has a least energy sign-changing solution \(u_b \in {\mathcal {M}}_b^{\lambda }\) with precisely two nodal domains such that \(I_b^{\lambda }(u_b) = \inf _{u\in {\mathcal {M}}_b^{\lambda }} I_b^{\lambda }(u)\).
Another goal of this paper is to establish the so-called energy doubling property (cf. [45]), i.e., the energy of any sign-changing solution of problem (1.1) is strictly larger than twice the ground state energy. For the semilinear equation problem (2.6), the conclusion is trivial. Indeed, if we denote the Nehari manifold associated to problem (2.6) by
and define
then it is easy to verify that \(u^\pm \in {\mathcal {N}}\) for any sign-changing solution \(u \in W^{s,p}_0(\Omega )\) to problem (2.6). We can deduce that
We may point out that the minimizer of (2.10) is indeed a ground state solution of problem (2.6) and \(c > 0\) is the least energy of all weak solutions of problem (2.6). Therefore, by (2.11), it follows that the energy of any sign-changing solution of problem (2.6) is larger than twice the least energy. When \(b > 0\), a similar result was obtained by Shuai [38] in a bounded domain \(\Omega \). We are also interested in that whether property (2.11) is still true for problem (1.1). To answer this question, we have the following result:
Theorem 2.2
There exists \(\lambda ^{**} > 0\) such that for all \(\lambda \ge \lambda ^{**}\), the \(c^*:= \inf _{u \in {\mathcal {N}}_b^{\lambda }}I_b^{\lambda }(u) > 0\) is achieved and \(I_b^{\lambda }(u) > 2c^*\), where \({\mathcal {N}}_b^{\lambda } = \left\{ u \in W^{s,p}_0(\Omega ){\setminus }\{0\}\ |\ \langle (I_b^{\lambda })'(u), u \rangle = 0 \right\} \) and u is the least energy sign-changing solution obtained in Theorem 2.1. In particular, \(c^*> 0\) is achieved either by a positive or a negative function.
It is obvious that the energy of the sign-changing solution \(u_b\) obtained in Theorem 2.1 depends on b. In the following, we give a convergence property of \(u_b\) as \(b \rightarrow 0\), which reflects some relationship between \(b > 0\) and \(b = 0\) for problem (1.1).
Theorem 2.3
For any sequence \(\{b_n\}\) with \(b_n \rightarrow 0\) as \(n \rightarrow \infty \), there exists a subsequence, still denoted by \(\{b_n\}\), such that \(\{u_n\}\) converges to \(u_0\) strongly in \(W^{s,p}_0(\Omega )\) as \(n \rightarrow \infty \), where \(u_0\) is a least energy sign-changing solution to the following problem
The plan of this paper is as follows: Sect. 2 covers the proof of the achievement of least energy for the constraint problem (1.1), Sect. 3 is devoted to the proofs of our main theorems.
Throughout this paper, we use standard notations. For simplicity, we use “\(\rightarrow \)” and “\(\rightharpoonup \)” to denote the strong and weak convergence in the related function space respectively. Various positive constants are denoted by C and \( C_{i}.\) We use “:=” to denote definitions and \(B_r (x) := \{y \in {\mathbb {R}}^N \ |\ |x -y| < r\}.\) We denote a subsequence of a sequence \(\{u_n \}_n\) as \(\{u_n \}_n\) to simplify the notation unless specified.
3 Some technical lemmas
Now, fixed \(u \in W^{s,p}_0(\Omega )\) with \(u^{\pm } \ne 0\), we define function \(\psi _u : [0, \infty ) \times [0, \infty ) \rightarrow {\mathbb {R}}\) and mapping \(T_u : [0, \infty ) \times [0, \infty ) \rightarrow {\mathbb {R}}^2\) by
and
Lemma 3.1
For any \(u \in W^{s,p}_0(\Omega )\) with \(u^{\pm } \ne 0\), then there is the unique maximum point pair \((\alpha _u, \beta _u)\) of the function \(\psi _u\) such that \(\alpha _uu^+ + \beta _uu^- \in \mathcal {M}_b^{\lambda }\).
Proof
Our proof will be divided into three steps.
Step 1 For any \(u \in W^{s,p}_0(\Omega )\) with \(u^{\pm } \ne 0\), in the following, we will prove the existence of \(\alpha _u\) and \(\beta _u\).
From assumptions, we have that
for all \(r \in (q, p_s^*)\). Then for any \(\varepsilon > 0\), there exists \(C_\varepsilon > 0\) such that
Since \(4 \le 2p< q < p_s^*\), it follows from (3.4) and the Sobolev embedding theorem that
Choose \(\varepsilon > 0\) such that \((a - \lambda \varepsilon C_1) > 0\). Since \(p_s^{*}, r > 2p\), we have that \(\langle (I_b^{\lambda })'(\alpha u^+ + \beta u^-), \alpha u^+\rangle > 0\) for \(\alpha \) small enough and all \(\beta \ge 0\).
Similarly, we obtain that \(\langle (I_b^{\lambda })'(\alpha u^+ + \beta u^-), \beta u^-\rangle > 0\) for \(\beta \) small enough and all \(\alpha \ge 0\).
Therefore, there exists \(\delta _1 > 0\) such that
for all \(\alpha , \beta \ge 0\).
On the other hand, we can choose \(\alpha = \delta _2^*> \delta _1\), if \(\beta \in [\delta _1, \delta _2^*]\) and \(\delta _2^*\) is large enough, it follows that
Similarly, we have that
Let \(\delta _2 > \delta _2^*\) be large enough, we obtain that
for all \(\alpha , \beta \in [\delta _1, \delta _2]\).
Combining (3.5) and (3.6) with Miranda’s theorem [33], there exists \((\alpha _u, \beta _u) \in (0, +\infty ) \times (0, +\infty )\) such that \(T_u(\alpha , \beta )= (0, 0)\), i.e., \(\alpha u^+ + \beta u^- \in \mathcal {M}_b^{\lambda }\).
Step 2 In this step, we prove the uniqueness of the pair \((\alpha _u, \beta _u)\).
\(\bullet \) Case \(u \in \mathcal {M}_b^{\lambda }\).
If \(u \in \mathcal {M}_b^{\lambda }\), we have that
and
We show that \((\alpha _u, \beta _u) = (1, 1)\) is the unique pair of numbers such that \(\alpha _u u^+ + \beta _u u^- \in \mathcal {M}_b^{\lambda }\).
Let \((\alpha _0, \beta _0)\) be a pair of numbers such that \(\alpha _0 u^+ + \beta _0 u^- \in \mathcal {M}_b^{\lambda }\) with \(0 < \alpha _0 \le \beta _0\). Hence, one has that
and
According to \(0 < \alpha _0 \le \beta _0\) and (3.10), we have that
If \(\beta _0 > 1\), by (3.8) and (3.11), one has that
This is a contradiction. Therefore, we conclude that \(0 < \alpha _0 \le \beta _0 \le 1\).
Similarly, by (3.9) and \(0 < \alpha _0 \le \beta _0\), we have that
This fact implies that \(\alpha _0 \ge 1\). Consequently, \(\alpha _0 = \beta _0 = 1\).
\(\bullet \) Case \(u \not \in \mathcal {M}_b^{\lambda }\).
Suppose that there exist \((\alpha _1, \beta _1)\), \((\alpha _2, \beta _2)\) such that
Hence
By \(\omega _1 \in \mathcal {M}_b^{\lambda }\), one has that
Hence, \(\alpha _1 = \alpha _2\), \(\beta _1 = \beta _2\).
Step 3 In this step, we will prove that \((\alpha _u, \beta _u)\) is the unique maximum point of \(\psi _u\) on \([0, \infty ) \times [0, \infty )\).
First, it is easy to see that
Let \(\Omega ^+ = \{x \in \Omega : u(x) > 0\}\) and \(\Omega ^- = \{x \in \Omega : u(x) < 0\}\), \(u \in W^{s,p}_0(\Omega )\) with \(u^{\pm } \ne 0\), we have that
Combining (3.12) and (3.13), we have that
which implies that \(\lim _{|(\alpha ,\beta )|\rightarrow \infty }\psi _u(\alpha ,\beta ) = -\infty \) since \(p_s^{*} > 2p\). Hence, \((\alpha _u, \beta _u)\) is the unique critical point of \(\psi _u\) in \([0, \infty ) \times [0, \infty )\). So it is sufficient to check that a maximum point cannot be achieved on the boundary of \([0, \infty ) \times [0, \infty )\). By contradiction, we suppose that \((0, \beta _0)\) is a maximum point of \(\psi _u\) with \(\beta _0 \ge 0\). Then, we have that
Therefore, it is obvious that
if \(\alpha \) is small enough. That is, \(\psi _u\) is an increasing function with respect to \(\alpha \) if \(\alpha \) is small enough. This yields the contradiction. Similarly, \(\psi _u\) can not achieve its global maximum on \((\alpha , 0)\) with \(\alpha \ge 0\). \(\square \)
Lemma 3.2
For any \(u \in W^{s,p}_0(\Omega )\) with \(u^{\pm } \ne 0\) such that \(\langle (I_b^{\lambda })'(u), u^{\pm }\rangle \le 0\). Then, the unique maximum point of \(\psi _u\) on \([0, \infty ) \times [0, \infty )\) satisfies \(0 < \alpha _u, \beta _u \le 1\).
Proof
Without loss of generality, let \(\alpha _u \ge \beta _u > 0\).
On the one hand, by \(\alpha _uu^+ + \beta _uu^- \in \mathcal {M}_b^{\lambda }\), we have
On the other hand, by \(\langle (I_b^{\lambda })'(u), u^+ \rangle \le 0\), we have
So, according to (3.14) and (3.15), we have that
If \(\alpha _u \ge 1\), one has
This fact together with (3.16), we have
This is a contradiction. Thus, we conclude that \(\alpha _u \le 1\). Thus, we have that \(0 < \alpha _u, \beta _u \le 1\). \(\square \)
Lemma 3.3
Let \(c_b^{\lambda } = \inf _{u \in \mathcal {M}_b^{\lambda }}I_b^{\lambda }(u)\), then we have that \(\lim _{\lambda \rightarrow \infty }c_b^{\lambda } = 0\).
Proof
For any \(u \in \mathcal {M}_b^{\lambda }\), we have
Then, by (3.4) and the Sobolev theorem, we have that
Thus, we get
Choosing \(\varepsilon \) small enough such that \(1 - \lambda \varepsilon C_1 > 0\), since \(r, p_s^{*} > p\), there exists \(\rho > 0\) such that
On the other hand, for any \(u \in \mathcal {M}_b^{\lambda }\), it is obvious that \(\langle (I_b^{\lambda })'(u), u \rangle = 0\). Then, we have
From above discussions, we have that \(I_b^{\lambda }(u) > 0\) for all \(u \in \mathcal {M}_b^{\lambda }\). Therefore, \(I_b^{\lambda }\) is bounded below on \(\mathcal {M}_b^{\lambda }\), that is \(c_b^{\lambda } = \inf _{u \in \mathcal {M}_b^{\lambda }}I_b^{\lambda }(u)\) is well defined.
Let \(u \in W^{s,p}_0(\Omega )\) with \(u^\pm \ne 0\) be fixed. By Lemma 3.1, for each \(\lambda > 0\), there exist \(\alpha _\lambda , \beta _\lambda > 0\) such that \(\alpha _\lambda u^+ +\beta _\lambda u^- \in \mathcal {M}_b^{\lambda }\). By using Lemma 3.1 again, we have that
To our end, we just prove that \(\alpha _\lambda \rightarrow 0\) and \(\beta _\lambda \rightarrow 0\) as \(\lambda \rightarrow \infty \).
Let
where \(T_u\) is defined as (3.2). By (3.3), we have that
Hence, \(\mathcal {T}_u\) is bounded since \(2p < p_s^{*}\). Let \(\{\lambda _n\} \subset (0, \infty )\) be such that \(\lambda _n \rightarrow \infty \) as \(n \rightarrow \infty \). Then, there exist \(\alpha _0\) and \(\beta _0\) such that \((\alpha _{\lambda _n}, \beta _{\lambda _n}) \rightarrow (\alpha _0, \beta _0)\) as \(n \rightarrow \infty \).
Now, we claim \(\alpha _0 = \beta _0 = 0\). Suppose, by contradiction, that \(\alpha _0 > 0\) or \(\beta _0 > 0\). By \(\alpha _{\lambda _n} u^+ +\beta _{\lambda _n} u^- \in \mathcal {M}_b^{\lambda _n}\), for any \(n \in {\mathbb {N}}\), we have
Thanks to \(\alpha _{\lambda _n} u^+ \rightarrow \alpha _0 u^+\) and \(\beta _{\lambda _n} u^- \rightarrow \beta _0 u^+\) in \(W^{s,p}_0(\Omega )\), (3.4) and the Lebesgue dominated convergence theorem, we have that
as \(n \rightarrow \infty \). It follows from \(\lambda _n \rightarrow \infty \) as \(n \rightarrow \infty \) and \(\{\alpha _{\lambda _n} u^+ +\beta _{\lambda _n} u^-\}\) is bounded in \(W^{s,p}_0(\Omega )\) that we have a contradiction with equality (3.18). Hence, \(\alpha _0 = \beta _0 = 0\).
Hence, we conclude that \(\lim _{\lambda \rightarrow \infty } c_b^{\lambda } = 0\). \(\square \)
Lemma 3.4
There exists \(\lambda ^*> 0\) such that for all \(\lambda \ge \lambda ^*\), the infimum \(c_b^{\lambda }\) is achieved.
Proof
By the definition of \(c_b^{\lambda }\), there exists a sequence \(\{u_n\} \subset \mathcal {M}_b^{\lambda }\) such that
Obviously, \(\{u_n\}\) is bounded in \(W^{s,p}_0(\Omega )\). Then, up to a subsequence, still denoted by \(\{u_n\}\), there exists \(u \in W^{s,p}_0(\Omega )\) such that \(u_n \rightharpoonup u\). Since the embedding \(W^{s,p}_0(\Omega )\hookrightarrow L^t(\Omega )\) is compact, for all \(t \in (p, p_s^{*})\), we have
Hence
By Lemma 3.1, we have that
for all \(\alpha , \beta \ge 0\).
On the one hand, the Vitali convergence theorem yields that
On the other hand, since \(u_n \rightarrow u\) in \(L^q(\Omega )\), we have
Then, by (3.19), (3.20), Brézis–Lieb lemma and the weak semicontinuity of norm, we have
where
That is, one has that
for all \(\alpha \ge 0\) and all \(\beta \ge 0\).
Now, we claim that \(u^\pm \ne 0\).
In fact, since the situation \(u^- \ne 0\) is analogous, we just prove \(u^+ \ne 0\). By contradiction, we suppose \(u^+ = 0\). Hence, let \(\beta = 0\) in (3.17) and we have that
for all \(\alpha \ge 0\).
Case 1: \(B_1=0\).
If \(A_1=0\), that is, \(u_n^+ \rightarrow u^+\) in \(W^{s,p}_0(\Omega )\). In view of Lemma (3.22), we obtain \(\Vert u^+\Vert >0\), which contradicts our supposition. If \(A_1>0\), by (3.22), we have that
for all \(\alpha \ge 0\), which is absurd by Lemma 3.3. Anyway, we have a contradiction.
Case 2: \(B_1>0\).
One one hand, by Lemma 3.3, there exists \(\lambda ^*> 0\) such that
where \(S>0\) is given by (2.2).
On the other hand, since \(B_1>0\), we obtain \(A_1>0\). Hence, in view of (3.22), we have that
which is a contradiction. That is, we deduce that \(u^\pm \ne 0\).
Second, we prove \(B_1=B_2=0\).
Since the situation \(B_2=0\) is analogous, we only prove \(B_1=0\). By contradiction, we suppose that \(B_1>0\).
Case 1: \(B_2>0\).
According to \(B_1,B_2>0\) and Sobolev embedding, we obtain that \(A_1,A_2>0\). Let
It is easy to see that \(\phi (\alpha )>0\) for \(\alpha > 0\) small enough and \(\phi (\alpha ) <0\) for \(\alpha < 0\) large enough. Hence, by continuous of \(\phi (\alpha )\), there exists \({\hat{\alpha }}>0\) such that
Similarly, there exists \({\hat{\beta }}>0\) such that
Since \([0,{\hat{\alpha }}]\times [0, {\hat{\beta }}]\) is compact and \(\phi \) is continuous, there exists \((\alpha _u, \beta _u)\in [0,{\hat{\alpha }}]\times [0, {\hat{\beta }}]\) such that
Now, we prove that \((\alpha _u, \beta _u) \in (0,{\hat{\alpha }})\times (0, {\hat{\beta }})\).
Note that, if \(\beta \) is small enough, we have that
for all \(\alpha \in [0,{\hat{\alpha }}]\).
Hence, there exists \(\beta _0\in [0, {\hat{\beta }}]\) such that
That is, any point of \((\alpha , 0)\) with \(0\le \alpha \le {\hat{\alpha }}\) is not the maximizer of \(\phi \). Hence, \((\alpha _u, \beta _u)\notin [0,{\hat{\alpha }}]\times \{0\}\). Similarly, we obtain \((\alpha _u,\beta _u)\notin \{0\}\times [0,{\hat{\alpha }}]\).
On the other hand, it is easy to see that
and
for \(\alpha \in (0,{\hat{\alpha }}]\), \(\beta \in (0, {\hat{\beta }}]\).
Then, we have that
and
for all \(\alpha \in [0,{\hat{\alpha }}]\) and all \(\beta \in [0, {\hat{\beta }}]\).
Therefore, according to (3.21), we conclude that
for all \(\alpha \in [0,{\hat{\alpha }}]\) and all \(\beta \in [0, {\hat{\beta }}]\).
Hence,\((\alpha _u, \beta _u)\notin \{{\hat{\alpha }}\}\times [0, {\hat{\beta }}]\) and \((\alpha _u, \beta _u)\notin [0,{\hat{\alpha }}]\times \{{\hat{\beta }}\}\).
Finally, we get that \((\alpha _u, \beta _u)\in (0,{\hat{\alpha }})\times (0, {\hat{\beta }})\). Hence, it follows that \((\alpha _u, \beta _u)\) is a critical point of \(\psi \).
Hence, \(\alpha _u u^+ + \beta _u u^-\in {\mathcal {M}}_b^{\lambda }\). From (3.17), (3.20), and (3.21), we have that
which is a contradiction.
Case 2: \(B_2 = 0\).
In this case, we can maximize in \([0, {\hat{\alpha }}]\times [0, \infty )\). Indeed, it is possible to show that there exist \(\beta _0\in [0, \infty )\) such that
Hence, there is \((\alpha _u, \beta _u)\in [0, {\hat{\alpha }}]\times [0, \infty )\) such that
In the following, we prove that \((\alpha _u, \beta _u)\in (0, {\hat{\alpha }})\times (0, \infty )\).
It is noted that \(\phi (\alpha ,0) < \phi (\alpha , \beta )\) for \(\alpha \in [0,{\hat{\alpha }}]\) and \(\beta \) small enough, so we have \((\alpha _u, \beta _u)\notin [0,{\hat{\alpha }}]\times \{0\}\).
Meanwhile, \(\phi (0,\beta ) < \phi (\alpha , \beta )\) for \(\beta \in [0, \infty )\) and \(\alpha \) small enough, then we have \((\alpha _u, \beta _u)\notin \{0\}\times [0, \infty )\).
On the other hand, it is obvious that
for all \(\beta \in [0, \infty )\).
Hence, we have that \(\phi ({\hat{\alpha }}, \beta )\le 0\) for all \(\beta \in [0, \infty )\). Thus, \((\alpha _u, \beta _u)\notin \{{\hat{\alpha }}\}\times [0, \infty )\). Hence, \((\alpha _u, \beta _u)\in (0,{\hat{\alpha }})\times (0, \infty )\). That is, \((\alpha _u, \beta _u)\) is an inner maximizer of \(\phi \) in \([0,{\hat{\alpha }}) \times [0, \infty )\). Hence, \(\alpha _u u^+ + \beta _u u^-\in {\mathcal {M}}_b^{\lambda }\).
Hence, in view of (3.24), we have that
which is a contradiction.
Therefore, from the above arguments, we have that \(B_1 = B_2 = 0\).
Finally, we prove that \(c_b^{\lambda }\) is achieved.
Since \(u^\pm \ne 0\), by Lemma 3.1, there exist \(\alpha _u, \beta _u > 0\) such that
Furthermore, it is easy to see that
By Lemma 3.2, we obtain \(0<\alpha _u, \beta _u \le 1\).
Since \(u_n\in {\mathcal {M}}_b^{\lambda }\), according to Lemma 3.3, we get
Thanks to \(B_1 = B_2 = 0\) and the norm in \(W^{s,p}_0(\Omega )\) is lower semicontinuous, and we have that
Therefore, \(\alpha _u=\beta _u=1\), and \(c_b^{\lambda }\) is achieved by \(u_b:= u^+ + u^-\in {\mathcal {M}}_b^{\lambda }\). \(\square \)
4 Proof of Theorems
In this section, we prove our main results. First, we prove Theorem 2.1. In fact, thanks to Lemma 3.4, we just prove that the minimizer \(u_b\) for \(c_b^{\lambda }\) is indeed a sign-changing solution of problem (1.1).
Proof of Theorem 2.1
Since \(u_b\in {\mathcal {M}}_b^{\lambda }\), we have \(\langle (I_b^{\lambda })'(u_b), u_b^+\rangle =\langle (I_b^{\lambda })'(u_b),u_b^-\rangle =0\). By Lemma 3.4, for \((\alpha ,\beta )\in ({\mathbb {R}}_+\times {\mathbb {R}}_+)\backslash (1,1)\), we have
Arguing by contradiction, we assume that \((I_b^{\lambda })'(u_b)\ne 0\), then there exist \(\delta > 0\) and \(\iota > 0\) such that
Choose \(\tau \in (0,\min \{1/2,\frac{\delta }{\sqrt{2}\Vert u_b\Vert }\})\). Let
and
In view of (4.1), it is easy to see that
Let \(\varepsilon := \min \{(c_b^{\lambda } -\bar{c}_\lambda )/3,\iota \delta /8\}\) and \(S_\delta := B(u_b,\delta )\), according to Lemma 2.3 in [46], there exists a deformation \(\eta \in C([0,1]\times D,D)\) such that
-
(a)
\(\eta (1,v) = v\) if \(v\notin (I_b^{\lambda })^{-1}([c_b^{\lambda }-2\varepsilon , c_b^{\lambda }+2\varepsilon ]\cap S_{2\delta })\),
-
(b)
\(\eta (1,(I_b^{\lambda })^{c_b^{\lambda }+\varepsilon }\cap S_{\delta }) \subset (I_b^{\lambda })^{c_{b,\lambda }-\varepsilon }\),
-
(c)
\(I_b^{\lambda }(\eta (1,v))\le I_b^{\lambda })(v)\) for all \(v\in W^{s,p}_0(\Omega )\).
First, from (b) and Lemma 3.2, it is easy to see that
Next, we prove that \(\eta (1,g(D))\cap {\mathcal {M}}_b^{\lambda } \ne \emptyset \) , which contradicts the definition of \(c_b^{\lambda }\).
Let \(\gamma (\alpha ,\beta ):=\eta (1,g(\alpha ,\beta ))\) and
and
Since \(u_b \in {\mathcal {M}}_b^{\lambda }\), by the direct calculation, we have
and
Similarly, we have
and
Let
Then, we have that
Since \(\Psi _0(\alpha ,\beta )\) is a \(C^1\) function and (1, 1) is the unique isolated zero point of \(\Psi _0\), by using the degree theory, we deduce that \(\deg (\Psi _0 ,D,0) = 1\).
Hence, combining (4.3) with (a), we obtain
Consequently, we obtain \(\deg (\Psi _1 ,D,0) = 1\). Therefore, \(\Psi _1(\alpha _0, \beta _0) = 0\) for some \((\alpha _0, \beta _0)\in D\) so that
which is contradicted to (4.3).
From the above discussions, we deduce that \(u_b\) is a sign-changing solution for problem (1.1).
Finally, we prove that u has exactly two nodal domains. To this end, we assume by contradiction that
where
are two connected open subsets of \(\Omega \), and
Setting \(v:= u_1 + u_2\) , we see that \(v^+ = u_1\) and \(v^- = u_2\), i.e., \(v^\pm \ne 0\). Then, there exist a unique pair \((\alpha _v, \beta _v)\) of positive numbers such that
Hence
Moreover, using the fact that \(\langle (I_b^{\lambda })'(u),u_i\rangle = 0\), we obtain \(\langle (I_b^{\lambda })'(v),v^\pm \rangle = -b\Vert v^\pm \Vert ^p\Vert u_3\Vert ^p < 0\).
From Lemma 3.1 (ii), we have that
On the other hand, we have that
Hence, by (3.15), we can obtain that
which is a contradiction, that is, \(u_3 = 0\) and \(u_b\) has exactly two nodal domains. \(\square \)
By Theorem 2.1, we obtain a least energy sign-changing solution \(u_b\) of problem (1.1). Next,we prove that the energy of \(u_b\) is strictly larger than two times the ground state energy.
Proof of Theorem 2.2
Similar to Proof of Lemma 3.3, there exists \(\lambda ^*_1 > 0\) such that for all \(\lambda \ge \lambda ^*_1\), and for each \(b > 0\), there exists \(v_b\in {\mathcal {N}}_b^{\lambda }\) such that \(I_b^{\lambda }(v_b)=c^*>0\). By standard arguments (see Corollary 2.13 in Ref. [22]), the critical points of the functional \(I_b^{\lambda }\) on \({\mathcal {N}}_b^{\lambda }\) are critical points of \(I_b^{\lambda }\) in \(W^{s,p}_0(\Omega )\), and we obtain \((I_b^{\lambda })'(v_b)=0\). That is, \(v_b\) is a ground state solution of (1.1).
According to Theorem 2.1, we know that the problem (1.1) has a least energy sign-changing solution \(u_b\), which changes sign only once when \(\lambda \ge \lambda ^*\).
Let
Suppose that \(u_b= u_b^+ + u_b^-\). As Proof of Lemma 3.1, there exist \(\alpha _{u_b^+} > 0\) and \(\beta _{u_b^-} > 0\) such that
Furthermore, Lemma 3.2 implies that \(\alpha _{u_b^+}, \beta _{u_b^-} \in (0, 1)\).
Therefore, in view of Lemma 3.1, we have that
Hence, it follows that \(c^* > 0\) cannot be achieved by a sign-changing function. \(\square \)
Finally, we close this section with the proof of Theorem 2.3. In the following, we regard \(b > 0\) as a parameter in problem (1.1).
Proof of Theorem 2.3
We shall proceed through several steps on analyzing the convergence property of \(u_b\) as \(b \rightarrow 0\), where \(u_b\) is the least energy sign-changing solution obtained in Theorem 2.1.
Step 1 For any sequence \(\{b_n\}\) as \(b_n \searrow 0\), \(\{u_{b_n}\}\) is bounded in \(W^{s,p}_0(\Omega )\).
Choose a nonzero function \(\omega \in C_0^\infty (\Omega )\) with \(\omega ^\pm = 0\). Similar to discussion as in Lemma 3.2, for any \(\lambda \in [0, 1]\), there exists a pair positive numbers \((\lambda _1, \lambda _2)\) independent of \(\lambda \), such that
Then by virtue of Lemma 3.1, we get that, for any \(b \in [0, 1]\), there exists a unique pair \((\alpha _\omega (b), \beta _\omega (b)) \in (0, 1] \times (0, 1]\) such that
Thus, for any \(\lambda \in [0, 1]\), we have
where \(C^*> 0\) is a constant independent of \(\lambda \). So, let \(n \rightarrow \infty \), it follows that
which implies that \(\{u_{b_n}\}\) is bounded in \(W^{s,p}_0(\Omega )\).
Step 2 Problem (2.12) possesses one sign-changing solution \(u_0\).
Since \(\{u_{b_n}\}\) is bounded in \(W^{s,p}_0(\Omega )\), according to Step 1, going if necessary to a subsequence, there exists \(u_0 \in W^{s,p}_0(\Omega )\) such that
Since \(\{u_{b_n}\}\) is a weak solution of (1.1) with \(b = b_n\), we have
for all \(v \in C_0^\infty (\Omega )\), L(u, v) is defined by (2.5).
From (4.5), (4.6) and Step 1, we find that
for all \(\nu \in C_0^\infty (\Omega )\), which in turn implies that \(u_0\) is a weak solution of problem (2.12). By a similar argument as in the proof of Lemma 3.3, we conclude that \(u_0^{\pm } \ne 0\). Therefore, we complete the proof of the Step 2.
Step 3 Problem (2.12) possesses a least energy sign-changing solution \(v_0\), and there exists a unique pair \((\alpha _{b_n}, \beta _{b_n}) \in [0, \infty ) \times [0, \infty )\) such that \(\alpha _{b_n}v_0^+ + \beta _{b_n}v_0^- \in {\mathcal {M}}_{b_n}^{\lambda }\). Moreover, \((\alpha _{b_n}, \beta _{b_n}) \rightarrow (1, 1)\) as \(n \rightarrow \infty \).
By a similar argument to the proof of Theorem 2.1, we have that problem (2.12) possesses a least energy sign-changing solution \(v_0\), where \(I_0^{\lambda }(v_0) = c_0\) nod and \((I_0^{\lambda })'(v_0) = 0\). Then, by Lemma 3.1, we can easily obtain the existence and uniqueness of the pair \((\alpha _{b_n}, \beta _{b_n})\) such that \(\alpha _{b_n}v_0^+ + \beta _{b_n}v_0^- \in {\mathcal {M}}_{b_n}^{\lambda }\). Moreover, we have \(\alpha _{b_n} > 0\) and \(\beta _{b_n} > 0\). Then the claim will follow once we can prove that \((\alpha _{b_n}, \beta _{b_n}) \rightarrow (1, 1)\) as \(n \rightarrow \infty \). In fact, since \(\alpha _{b_n}v_0^+ + \beta _{b_n}v_0^- \in {\mathcal {M}}_{b_n}^{\lambda }\), we have that
and
From the convergence of \(b_n\) as \(n \rightarrow \infty \), we deduce that the sequences \(\{\alpha _{b_n}\}\) and \(\{\beta _{b_n}\}\) are bounded. Up to a subsequence, suppose that \(\alpha _{b_n} \rightarrow \alpha _0\) and \(\beta _{b_n} \rightarrow \beta _0\). Then it follows from (4.8) and (4.9) that
and
Thanks to \(v_0\) is a sign-changing solution of problem (2.12), we get
Hence, in view of (4.10)–(4.12), we can easily obtain that \((\alpha _{0}, \beta _{0}) = (1, 1)\), and the Step 3 follows.
Now, we can now give the proof of Theorem 2.3. We assert that \(u_0\) obtained in Step 2 is a least energy solution of problem (2.12). In fact, by virtue of Step 3 and Lemma 3.1, we find that
Hence, the proof of Theorem 2.3 is completed. \(\square \)
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Acknowledgements
S. Liang was supported by the Foundation for China Postdoctoral Science Foundation (Grant No. 2019M662220), Natural Science Foundation of Jilin Province, Research Foundation during the 13th Five-Year Plan Period of Department of Education of Jilin Province, China (JJKH20181161KJ), Natural Science Foundation of Changchun Normal University (No. 2017-09).
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Liang, S., Rădulescu, V.D. Least-energy nodal solutions of critical Kirchhoff problems with logarithmic nonlinearity. Anal.Math.Phys. 10, 45 (2020). https://doi.org/10.1007/s13324-020-00386-z
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DOI: https://doi.org/10.1007/s13324-020-00386-z