The study addresses the solution of a nonhomogeneous linear
differential equation of fractional order α, equal to the modified Bessel
function of order zero (I₀(x)), under the initial condition (f(0) = 0) and with
(0 < α < 1). The Caputo definition of the fractional derivative is
adopted, which is widely used in the analysis of physical and chemical phenomena
such as viscoelasticity, anomalous diffusion, and electrical circuits. By means
of the Laplace transform and its inverse, analytical solutions are obtained for
the specific cases (α = 1/4, 1/2, 3/4), expressed in terms of hypergeometric
functions 2F1. These solutions combine a fractional power of the independent
variable (x) with a special function, reflecting the non-integer nature of the
differential operator. Furthermore, regular patterns are observed in the
parameters of the hypergeometric functions as α varies, suggesting a
generalizable structure for other fractional values. The work demonstrates that
fractional differential equations can be systematically solved using classical
tools of integral and transform calculus, connecting fractional derivatives
with families of special functions.
Author(s) Details
Jorge Olivares
University of Antofagasta, Chile.
Pablo Martin
University of Antofagasta, Chile.
Fernando Maass
University of Antofagasta, Chile.
Please see the book here :- https://doi.org/10.9734/bpi/psniad/v3/6604
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