Equations involving fractional Laplacian operator: Compactness and application

Abstract: Abstract. In this paper, we consider the following problem involving fractional Laplacian operator:where Ω is a smooth bounded domain in. We show that for any sequence of solutions u n of (1) corresponding to ε n ∈ [0, 2 * α − 2), satisfying u n H ≤ C in the Sobolev space H defined in (1.2), u n converges strongly in H provided that N > 6α and λ > 0. An application of this compactness result is that problem (1) possesses infinitely many solutions under the same assumptions.

“…In [10], Caffarelli and Silvestre given a new local realization of the fractional Laplacian (−Δ) s by introducing the so-called s-harmonic extension. After that, several authors, using the localization method, have extended some results of the classical elliptic problems to the fractional Laplacian, see for example [2,5,7,13,16,31,34,35,36,24,25,26] and the references therein. In particular, Chang and Wang [16], using the method of invariant sets of descending flow, obtained the existence and multiplicity of nodal solutions for the elliptic equaitons involving the fractional Laplacian (−Δ) s for all s ∈ (0, 1) with subcritical nonlinearities; for the Brézis-Nirenberg type problem involving the fractional Laplacian (1.1), Tan [31] proved the existence of positive solutions with the special case s = 1 2 and Barrios et al [2] studied the general case with 0 < s < 1.…”

“…In particular, Chang and Wang [16], using the method of invariant sets of descending flow, obtained the existence and multiplicity of nodal solutions for the elliptic equaitons involving the fractional Laplacian (−Δ) s for all s ∈ (0, 1) with subcritical nonlinearities; for the Brézis-Nirenberg type problem involving the fractional Laplacian (1.1), Tan [31] proved the existence of positive solutions with the special case s = 1 2 and Barrios et al [2] studied the general case with 0 < s < 1. For any λ > 0, Yan et al [34] proved that problem (1.1) possesses infinitely many solutions by using a compactness result for the subcritical perturbed problem associated to (1.1). In [21] the authors study bifurcation and multiplicity of solutions for the fractional Laplacian with critical exponential nonlinearity using critical point theorem of Bartolo, Benci and Fortunato [3].…”

“…Multiplying the first eigenfunction and integrating both sides, one can easily check that if λ ≥ λ s 1 , any nontrivial solution of (1.1) is sign-changing. Therefore, by the results of [34], to prove Theorem 1.1, it suffices to consider the case of λ ∈ (0, λ s 1 ). Theorem 1.1 extends the result in [23] to the fractional Laplacian.…”

“…We show that, for each λ > 0, this problem has infinitely many sign-changing solutions by using a compactness result obtained in [34] and a combination of invariant sets method and Ljusternik-Schnirelman type minimax method.MSC 2010 : Primary 35J60; Secondary 47J30, 58E05 …”

Infinitely many sign-changing solutions for the Brézis-Nirenberg problem involving the fractional Laplacian

“…In [10], Caffarelli and Silvestre given a new local realization of the fractional Laplacian (−Δ) s by introducing the so-called s-harmonic extension. After that, several authors, using the localization method, have extended some results of the classical elliptic problems to the fractional Laplacian, see for example [2,5,7,13,16,31,34,35,36,24,25,26] and the references therein. In particular, Chang and Wang [16], using the method of invariant sets of descending flow, obtained the existence and multiplicity of nodal solutions for the elliptic equaitons involving the fractional Laplacian (−Δ) s for all s ∈ (0, 1) with subcritical nonlinearities; for the Brézis-Nirenberg type problem involving the fractional Laplacian (1.1), Tan [31] proved the existence of positive solutions with the special case s = 1 2 and Barrios et al [2] studied the general case with 0 < s < 1.…”

“…In particular, Chang and Wang [16], using the method of invariant sets of descending flow, obtained the existence and multiplicity of nodal solutions for the elliptic equaitons involving the fractional Laplacian (−Δ) s for all s ∈ (0, 1) with subcritical nonlinearities; for the Brézis-Nirenberg type problem involving the fractional Laplacian (1.1), Tan [31] proved the existence of positive solutions with the special case s = 1 2 and Barrios et al [2] studied the general case with 0 < s < 1. For any λ > 0, Yan et al [34] proved that problem (1.1) possesses infinitely many solutions by using a compactness result for the subcritical perturbed problem associated to (1.1). In [21] the authors study bifurcation and multiplicity of solutions for the fractional Laplacian with critical exponential nonlinearity using critical point theorem of Bartolo, Benci and Fortunato [3].…”

“…Multiplying the first eigenfunction and integrating both sides, one can easily check that if λ ≥ λ s 1 , any nontrivial solution of (1.1) is sign-changing. Therefore, by the results of [34], to prove Theorem 1.1, it suffices to consider the case of λ ∈ (0, λ s 1 ). Theorem 1.1 extends the result in [23] to the fractional Laplacian.…”

“…We show that, for each λ > 0, this problem has infinitely many sign-changing solutions by using a compactness result obtained in [34] and a combination of invariant sets method and Ljusternik-Schnirelman type minimax method.MSC 2010 : Primary 35J60; Secondary 47J30, 58E05 …”

Infinitely many sign-changing solutions for the Brézis-Nirenberg problem involving the fractional Laplacian

“…After that, the idea was developed to deal with various fractional boundary value problems such as fractional boundary value problem at resonance [5,6,9,10], Caputo fractional derivative problem [41], impulsive problem [7,31,33], nonlocal problem [4], integral boundary value problem [27], variational structure problem [21], fractional p-Laplace problem [15,20,25,26,34,40], fractional lower and upper solution problem [11,12,42], fractional delay problems, [30,32,44], solitons [16], Biological mathematics [17,29,43], etc. However, all above works were obtained with standard Riemann-Liouville or Caputo fractional derivatives.…”

Existence for fractional Dirichlet boundary value problem under barrier strip conditions

Fractional Kirchhoff problem with critical indefinite nonlinearity