Abstract
In this article, the ρ-Laplace transform is paired with a new iterative method to create a new hybrid methodology known as the new iterative transform method (NITM). This method is applied to analyse fractional-order third-order dispersive partial differential equations. The suggested technique procedure is straightforward and appealing, and it may be used to solve non-linear fractional-order partial differential equations effectively. The Caputo operator is used to express the fractional derivatives. Four numerical problems involving fractional-order third-order dispersive partial differential equations are presented with their analytical solutions. The graphs determined that their findings are in excellent agreement with the precise answers to the targeted issues. The solution to the problems at various fractional orders is achieved and found to be correct while comparing the exact solutions at integer-order problems. Although both problems are the non-linear fractional system of partial differential equations, the present technique provides its solution sophisticatedly. Including both integer and fractional order issues, solution graphs are carefully drawn. The fact that the issues’ physical dynamics completely support the solutions at both fractional and integer orders is significant. Moreover, despite using very few terms of the series solution attained by the present technique, higher accuracy is observed. In light of the various and authentic features, it can be customized to solve different fractional-order non-linear systems in nature.
Highlights
Fractional calculus (FC) has been a significant field of applied sciences for a few decades
To examine fractional-order ODEs and partial differential equations (PDEs) in the sense of Caputo fractional derivative, we proposed a new iterative approach using ρ-Laplace transform
The aim this article to investigate an approximate result of the third-order fractional dispersive PDEs, implemented the analytical technique
Summary
Fractional calculus (FC) has been a significant field of applied sciences for a few decades They model actual phenomena with fractional-order integral and derivative answers better than classical derivatives. Due to its appealing applications, FC is a significant study subject for most scholars, and the analysis of fractional-order partial differential equations (PDEs) has drawn special interest from several areas. Fractional-order differential equations (FPDES) have been studied to model various non-linear and complex phenomena in nature. FPDEs make a novel contribution towards various scientific research areas, such as a vast range of systems and processes, memories and other fields of science and engineering. FPDEs are implemented in many physical models in different fields of applied sciences, such as mathematical biology, fluid dynamics, chemical kinetics, fluid dynamics, linear optics, and quantum mechanics. Many fractional-order differential equations, including linear and non-linear fractional-order Zakherov–Kuznetsov equations, diffusion equations and Fokker-Planck equations, are solved using this innovative approach
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
