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Existence of the positive solutions for a tripled system of fractional differential equations via integral boundary conditions

Hojjat Afshari, Hadi Shojaat, Mansoureh SİAHKALİ MORADİ

2021Results in Nonlinear Analysis17 citationsDOIOpen Access PDF

Abstract

The purpose of this paper, is studying the existence andnonexistence of positive solutions to a class of a following tripledsystem of fractional differential equations. \begin{eqnarray*} \left\{ \begin{array}{ll}D^{\alpha}u(\zeta)+a(\zeta)f(\zeta,v(\zeta),\omega(\zeta))=0, \quad\quad u(0)=0,\quad u(1)=\int_0^1\phi(\zeta)u(\zeta)d\zeta, \\ \\D^{\beta}v(\zeta)+b(\zeta)g(\zeta,u(\zeta),\omega(\zeta))=0, \quad\quad v(0)=0,\quad v(1)=\int_0^1\psi(\zeta)v(\zeta)d\zeta,\\ \\D^{\gamma}\omega(\zeta)+c(\zeta)h(\zeta,u(\zeta),v(\zeta))=0,\quad\quad \omega(0)=0,\quad\omega(1)=\int_0^1\eta(\zeta)\omega(\zeta)d\zeta,\\ \end{array}\right.\end{eqnarray*} \\ where $0\leq \zeta \leq 1$, $1<\alpha,\beta, \gamma \leq 2$, $a,b,c\in C((0,1),[0,\infty))$, $ \phi, \psi,\eta \in L^1[0,1]$ are nonnegative and $f,g,h\inC([0,1]\times[0,\infty)\times[0,\infty),[0,\infty))$ and $D$ is the standard Riemann-Liouville fractional derivative.\\Also, we provide some examples to demonstrate the validity of ourresults.

Topics & Concepts

Zeta potentialOmegaRiemann zeta functionMathematical physicsMathematicsMathematical analysisPhysicsQuantum mechanicsNanoparticleNonlinear Differential Equations AnalysisDifferential Equations and Boundary ProblemsNonlinear Partial Differential Equations
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