Abstract
The authors of this paper solve the fractional space-time advection-dispersion equation (ADE). In the advection-dispersion process, the solute movement being nonlocal in nature and the velocity of fluid flow being nonuniform, it leads to form a heterogeneous system which approaches to model the same by means of a fractional ADE which generalizes the classical ADE, where the time derivative is substituted through the Caputo fractional derivative. For the study of such fractional models, various numerical techniques are used by the researchers but the nonlocality of the fractional derivative causes high computational expenses and complex calculations so the challenge is to use an efficient method which involves less computation and high accuracy in solving such models numerically. Here, in order to get the FADE solved in the form of convergent infinite series, a novel method NHPM (natural homotopy perturbation method) is applied which couples Natural transform along with the homotopy perturbation method. The homotopy peturbation method has been applied in mathematical physics to solve many initial value problems expressed in the form of PDEs. Also, the HPM has an advantage over the other methods that it does not require any discretization of the domains, is independent of any physical parameters, and only uses an embedding parameter p ∈ 0 , 1 . The HPM combined with the Natural transform leads to rapidly convergent series solutions with less computation. The efficacy of the used method is shown by working out some examples for time-fractional ADE with various initial conditions using the NHPM. The Mittag-Leffler function is used to solve the fractional space-time advection-dispersion problem, and the impact of changing the fractional parameter α on the solute concentration is shown for all the cases.
Highlights
Introduction and PreliminariesFractional calculus generalizes the integration and differentiation of integer order to arbitrary order that is being studied for the past 300 years
Fractional advection-dispersion equation describes the phenomena of anomalous diffusion of the particles in the transport process in a better way; as in anomalous diffusion, the solute transport is quicker or speedier than time’s inferred square root given by Baeumer et al [6]
The NHPM is successfully applied to find the solution for the general form of the space-time fractional advection-dispersion equation (ADE) and the analytic solution is found in terms of ML function for different cases
Summary
Fractional calculus generalizes the integration and differentiation of integer order to arbitrary order that is being studied for the past 300 years. The ADE arises in the study of transport of solute or Brownian motion of particles in a fluid occurring due to the simultaneous occurrence of advection and particle dispersion. The interest of the researchers lies in solving the FADE to find out the solute concentration at a particular instant of time and space. To solve the space-time fractional ADE, Momani and Odibat [7] utilized the ADM and variational iteration approach. The extended differential transform approach was used by Garg and Manohar [17] to solve the space-time fractional Fokker Planck (FFP) equation analytically. We gave a solution to the space-time ADE by the NHPM, and at the last, Section 6 contains some related examples, which show the efficiency of this method.
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