Positive solutions for fractional-order boundary value problems with or without dependence of integer-order ones

Abstract

We investigate the existence, non-existence, uniqueness, and multiplicity of positive solutions to the following problem: alignP \ arrayl D0+α u + h(t)f(u) = 0, 0<t<1, \\[1ex] u(0)=u(1)=0, array . align where D0+α is the Riemann-Liouville fractional derivative of order α∈(1,2]. Firstly, by considering the first eigenvalue λ1(α) of the corresponding eigenvalue problem, we establish the existence of positive solutions for both sublinear and superlinear cases involving λ1(α), thereby extending existing results in the literature. In addition, we address the issue of non-existence, which reinforces the sharpness of both hypotheses. Secondly, we demonstrate the uniqueness of positive solutions. For the sublinear case, we impose certain monotonicity conditions on f. For the superlinear case, we assume that h satisfies a specific condition to ensure the uniqueness of positive solutions when α =2. Near α =2, we prove uniqueness by leveraging the non-degeneracy of the unique solution, which represents a novel approach to studying fractional-order differential equations. Finally, we apply this methodology to establish the multiple existence of at least three positive solutions for H\'enon-type problems, which is also a new contribution.