Fundamental Spectral Theory of Fractional Singular Sturm-Liouville Operator

Sturm-Liouville problem was first developed in a number of papers that were published by these authors in 1836 and 1837. Charles-François Sturm (1803–1855), Professor of Mechanics at the Sorbonne, had been interested, since about 1833, in the problem of heat flow in bars, so he was well aware of eigenvalue-type problems. He worked closely with his friend Joseph Liouville (1809–1882), Professor ofMathematics at the Collège de France, on the general properties of second-order differential equations. Liouville also made many contributions to the general field of analysis, see [1]. A Sturm-Liouville boundary value problem consists of a second order linear ordinary differential equation


Introduction
Sturm-Liouville problem was first developed in a number of papers that were published by these authors in 1836 and 1837. Charles-François Sturm (1803-1855), Professor of Mechanics at the Sorbonne, had been interested, since about 1833, in the problem of heat flow in bars, so he was well aware of eigenvalue-type problems. He worked closely with his friend Joseph Liouville (1809-1882), Professor of Mathematics at the Collège de France, on the general properties of second-order differential equations. Liouville also made many contributions to the general field of analysis, see [1].
A Sturm-Liouville boundary value problem consists of a second order linear ordinary differential equation and boundary conditions. Here ( , ) is a bounded or unbounded open interval of the real line . The coefficients , , : ( , ) into ; ∈ C, the complex field. Spectral analysis finds applications in many diverse fields. Mathematical techniques could be developed into a more suitable and significant course by presenting them within the more general Sturm-Liouville theory in 2 . The Sturm-Liouville problems are important in many areas of science, engineering and mathematics. It is known that the spectral characteristics are spectra, spectral functions, scattering data, norming constants, etc. According to the theory linear second-order differential operator which is self-adjoint has an orthogonal sequence of eigenfunctions in 2 . Spectral properties of Sturm-Liouville operators are often derived, directly or indirectly, as a consequence of an established link between large distance asymptotic behavior of solutions of the associated differential equation and spectral properties of the corresponding differential operator. Sturm-Liouville problems are divided into regular and singular types. Differential equations such as Bessel, hydrogen atom, Hermitte, Jakobi, and Legendre equations can be transformed into Sturm-Liouville equations. There are many studies on these issues [2][3][4][5][6][7]. We also discuss the radial part of Schrödinger's equation for the Bessel equation.
Fractional calculus is "the theory of derivatives and integrals of any arbitrary real or complex order, which unify and generalize the notions of integer-order differentiation and -fold integration" [6][7][8][9][10][11][12][13]. In recent years, the concept of fractional calculus, originated from Leibniz, has achieved increasing interest during the last two decades. In particular, the last decade has scientific papers concerning fractional quantum mechanics. It has been proved that many systems in different fields of science and engineering can be modeled more accurately using fractional derivatives [8][9][10][11][12][13][14][15][16][17]. Fractional calculus has increasing importance for the last years because fractional calculus has been applied to almost every field of science. They are viscoelasticity, electrical engineering, electrochemistry, biology, biophysics and bioengineering, signal and image processing, mechanics, mechatronics, physics, and control theory. We note that ordinary derivatives in a traditional Sturm-Liouville problem are replaced with fractional derivatives, and the resulting problems are solved using some numerical methods [18][19][20][21][22][23]. Furthermore, Klimek and Argawal [24] define a fractional Sturm-Liouville operator, introduce a regular fractional Sturm-Liouville problem, and investigate the properties of the eigenfunctions and the eigenvalues of the operator. In this paper, our purpose is to introduce singular fractional Sturm-Liouville problem having Bessel type and prove spectral properties of spectral data for the operator.
Let us give the boundary value problem for Bessel equation and necessary data as follows.

Preliminaries
Now, consider the following Bessel equation: where and V are real numbers. The Bessel equation for having the analogous singularity is given in [5].
Definition 2 (see [10]). Let 0 < ≤ 1. The left-sided and right-sided Riemann-Liouville derivatives of order , respectively, are defined as follows: Analogous formulas yield the left-sided and right-sided Caputo derivatives of order : Definition 3 (see [14]). The general function Ψ ( ) is defined for ∈ C, , ∈ C, and , ∈ R ( = 1, . . . , ; = 1, . . . , ) by the series This general Wright function was investigated by Fox who presented its asymptotic expansion for large values of the argument under the condition If these conditions are satisfied, the series in (6) is convergent for any ∈ C.

A Singular Fractional Sturm-Liouville Problem for Bessel
Operator. Fractional Sturm-Liouville problem for Bessel operator denotes the differential part containing the left-and right-sided derivatives. Let us use the form of the integration by parts formulas (10), (11) for this new approximation. Properties of eigenfunctions and eigenvalues in the theory of classical Sturm-Liouville problems are related to the integration by parts formula for the first-order derivatives.
In the corresponding fractional version, we note that both left and right derivatives appear and the essential pairs are the left Riemann-Liouville derivative with the right Caputo derivative and the right Riemann-Liouville derivative with the left Caputo one. Spectral properties of Sturm-Liouville operators are often derived, directly or indirectly, as a consequence of an established link between large distance asymptotic behavior of solutions of the associated differential equation and spectral properties of the corresponding Bessel operator.
By means of equality (10) and boundary conditions (16), we obtain the identity (1) (1) The right-hand sides of (18) and (19) are equal; hence, we may see that the left sides are equal; that is, Proof. Let us observe that the following relation results from equality (10): Suppose that is the eigenvalue for (15)-(16) corresponding to eigenfunction ; the following equalities satisfy and its complex conjugate : (0) = 0, (0) = 0, where 2 1 + 2 2 ̸ = 0. We multiply (22)  (26) Now, we integrate over interval (0, 1], and applying relation (21), and we note that the right-hand side of the integrated equality contains only boundary terms: By virtue of the boundary conditions (23), (25), we find Because is a nontrivial solution and ( ) > 0, it is easily seen that = . The eigenvalues are real.
Integrating over interval (0, 1] and applying relation (21) we note that the right-hand side of the integrated equality contains only boundary terms: Using the boundary conditions (31), (33), we obtain that where 1 ̸ = 2 . Then, the eigenfunctions are orthogonal of this operator.

Remark 9.
Let us now give certain auxiliary functions. Because we use the functions, the first of them is as follows: where 1 Ψ 2 is the Fox-Wright function [14]: The properties of the function are determined by the parameters Considering Theorem 4, we note that this function is continuous in (0, 1] when order > 1/2, that is, > 1/2. For 0 < ≤ 1/2; it is discontinuous at end = 1. The explicitly calculated function allows to estimate the second component of stationary function 0 of the differential part of Sturm-Liouville operator which looks as follows: The next function is the following integral: Again, using Theorem 4 and calculating parameters according to (39), 6

Journal of Function Spaces and Applications
Finally, where the coefficient ( ) is and functions are defined in (41).
Proof. By means of composition rules, (15) can be rewritten as follows: The last equality suggests that is a stationary function of fractional singular Sturm-Liouville problem for Bessel operator.

Conclusion
In the paper, we have extended the scope of some spectral properties of singular fractional Sturm-Liouville problem. We pointed that its eigenvalues related to the Bessel operator with the certain boundary conditions are real and its eigenfunctions corresponding to distinct eigenvalues are orthogonal. Furthermore, we showed that fractional Bessel operator is self-adjoint. Spectral properties of Sturm-Liouville theory are applied to the fractional theory. Our results are important in point of the fractional Sturm-Liouville theory.