Positive Solutions for a Hadamard Fractional p-Laplacian Three-Point Boundary Value Problem

Abstract: This article is to study a three-point boundary value problem of Hadamard fractional p-Laplacian differential equation. When our nonlinearity grows ( p − 1 ) -superlinearly and ( p − 1 ) -sublinearly, the existence of positive solutions is obtained via fixed point index. Moreover, using an increasing operator fixed-point theorem, the uniqueness of positive solutions and uniform convergence sequences are also established.

“…Research on Hadamard fractional differential equations is at an early stage; see for example [19][20][21][22][23][24][25][26][27][28][29][30]. In [19], B. Ahmad and S. K. Ntouyas used fixed point theory to study the existence and uniqueness of solutions for a Hadamard type fractional differential equation involving integral boundary conditions…”

“…where f satisfies the Lipschitz condition. On the other hand, p-Laplacian equations are extensively used in physics, mechanics, dynamical systems, etc (see [15][16][17][18][20][21][22][23]31]). For example, Leibenson [31] introduced p-Laplacian differential equations to study a mechanics problem involving turbulent flow in a porous medium.…”

Positive Solutions for a Class of p-Laplacian Hadamard Fractional-Order Three-Point Boundary Value Problems

“…Research on Hadamard fractional differential equations is at an early stage; see for example [19][20][21][22][23][24][25][26][27][28][29][30]. In [19], B. Ahmad and S. K. Ntouyas used fixed point theory to study the existence and uniqueness of solutions for a Hadamard type fractional differential equation involving integral boundary conditions…”

“…where f satisfies the Lipschitz condition. On the other hand, p-Laplacian equations are extensively used in physics, mechanics, dynamical systems, etc (see [15][16][17][18][20][21][22][23]31]). For example, Leibenson [31] introduced p-Laplacian differential equations to study a mechanics problem involving turbulent flow in a porous medium.…”

Positive Solutions for a Class of p-Laplacian Hadamard Fractional-Order Three-Point Boundary Value Problems

“…In particular, the Hadamard derivative is a nonlocal fractional derivative with singular logarithmic kernel. So the study of Hadamard fractional differential equations is relatively difficult; see [26][27][28][29][30][31][32].…”

Positive Solutions for a Weakly Singular Hadamard-Type Fractional Differential Equation with Changing-Sign Nonlinearity

“…In recent years, to enrich the theory of fractional calculus, the fractional derivative and integral were extended to many different forms such as Hadamard, Erdelyi-Kober, Hilfer derivatives, and integrals. In particular, it is more difficult to obtain the qualitative properties of solutions for Hadamard-type fractional differential equations since Hadamard derivatives possess a singular logarithmic kernel [99][100][101][102][103][104][105][106].…”

Solutions for a Singular Hadamard-Type Fractional Differential Equation by the Spectral Construct Analysis