| [1] |
AtanganaA, QureshiS. Modeling attractors of chaotic dynamical systems with fractal fractional operators. Chaos Solitons Fractals. 2019;123:320‐337. · Zbl 1448.65268 |
| [2] |
AtanganaA. Blind in a commutative world: Simple illustrations with functions and chaotic attractors. Chaos Solitons Fractals. 2018;114:347‐363. · Zbl 1415.34009 |
| [3] |
HeZ, ZhangX, LiuL, WuY, CuiY. Existence and asymptotic analysis of positive solutions for a singular fractional differential equation with nonlocal boundary conditions. Bound Value Probl. 2018;2018:189. · Zbl 1499.34052 |
| [4] |
KilbasAA, TrujilloJJ. Differential equations of fractional order: methods results and problems I. Appl Anal. 2001;78:153‐192. · Zbl 1031.34002 |
| [5] |
KilbasAA, TrujilloJJ. Differential equations of fractional order: methods results and problems II. Appl Anal. 2002;81:435‐493. · Zbl 1033.34007 |
| [6] |
MillerKS, RossB. An Introduction to the Fractional Calculus and Fractional Differential Equations. New York:Wiley; 1993. · Zbl 0789.26002 |
| [7] |
PodlubnyI. Fractional Differential Equations, Mathematics in Science and Engineering. New York:Academic Press; 1999. · Zbl 0924.34008 |
| [8] |
SamkoSG, KilbasAA, MarichevOI. Fractional Integrals and Derivatives, Theory and applications. Yverdon:Gordon and Breach; 1993. · Zbl 0818.26003 |
| [9] |
ZhangX, LiuL, WuY. Multiple positive solutions of a singular fractional differential equation with negatively perturbed term. Math Comp Modeling. 2012;55:1263‐1274. · Zbl 1255.34010 |
| [10] |
ZhangX, LiuL, WuY. Variational structure and multiple solutions for a fractional advection—dispersion equation. Comp Math Appl. 2014;68(12):1794‐1805. · Zbl 1369.35108 |
| [11] |
BaiZ, LüH. Positive solutions for boundary value problem of nonlinear fractional differential equation. J Math Anal Appl. 2005;311:495‐505. · Zbl 1079.34048 |
| [12] |
CabadaA, HamdiZ. Nonlinear fractional differential equations with integral boundary value conditions. Appl Math Comp. 2014;228:251‐257. · Zbl 1364.34010 |
| [13] |
ZhangS. The existence of a positive solution for a nonlinear fractional differential equation. J Math Anal Appl. 2000;252:804‐812. · Zbl 0972.34004 |
| [14] |
AlqahtaniB, JaradF, FulgaA, KarapınarE. Nonlinear F‐contractions on b‐metric spaces and differential equations in the frame of fractional derivatives with Mittag‐Leffler kernel. Chaos, Solitons Fractals. 2019;128:349‐354. · Zbl 1483.54025 |
| [15] |
AlqahtaniB, AydiH, KarapınarE, Rakoc̆evićV. A solution for Volterra fractional integral equations by hybrid contractions. Mathematics. 2019;7:694. |
| [16] |
BakhtinIA. The contraction mapping principle in quasimetric spaces. Funct Anal. 1989;30:26‐37. · Zbl 0748.47048 |
| [17] |
CzerwikS. Contraction mappings in b‐metric spaces. Acta Math Inform Univ Ostrav. 1993;1:5‐11. · Zbl 0849.54036 |
| [18] |
BerindeV. Sequences of operators and fixed points in quasi‐metric spaces. Mathematica. 1996;41:23‐27. · Zbl 1005.54501 |
| [19] |
RusIA. Generalized Contractions and Applications. Romania:Cluj University Press; 2001. · Zbl 0968.54029 |
| [20] |
RusIA. The theory of a metrical fixed point theorem: theoretical and applicative relevances. Fixed Point Theory. 2008;9:541‐559. · Zbl 1172.54030 |
| [21] |
BerindeV. Contracţii Generalizate şi Aplicaţii, Vol. 2. Baia Mare, Romania:Editura Cub Press; 1997. · Zbl 0885.47022 |
| [22] |
AdıgüzelRS, KarapınarE, Erhanİ. A solution to nonlinear Volterra integro‐dynamic equations via fixed point theory. Filomat. 2019;33(16):5331‐5343. · Zbl 1499.45009 |
| [23] |
PacurarM. A fixed point result for φ‐contractions on b‐metric spaces without boundedness assumption. Fasciculi Math. 2010;43:127‐137. · Zbl 1196.54079 |
