Add to ORKGIn this paper, two-hybrid techniques, namely q-homotopy analysis Elzaki transform method (q-HAETM) and iterative Elzaki transform method (IETM) have been applied to obtain the numerical solutions of time-fractional Navier-Stokes equations in polar coordinate described in the Caputo sense. q-HAETM is the combination of the homotopy analysis method and Elzaki transform method, and IETM is the combination of two reliable methods, i.e. iterative method and Elzaki transform method. Two example problems are solved, and the obtained results are compared with the solutions solved by other techniques which show the efficacy and powerfulness of the methods
The idea proposed in this work is to extend the ZZ transform method to resolve the nonlinear fractio...
In this paper, we introduce a modified method which is constructed by mixing the residual power seri...
The main features of scientific efforts in physics and engineering are the development of models for...
In this article, we study the analytical solution of time-fractional Navier-Stokes equation based on...
In this paper, numerical solution of fractional order Navier-Stokes equations in unsteady viscous fl...
In this manuscript, a semianalytical solution of the time-fractional Navier-Stokes equation under Ca...
In this paper we will use the residual power series (RPS) method to generate the solution of the non...
This paper witnesses the coupling of two basic transforms: the He-Laplace transform (HLT) which is a...
In this paper, we present a reliable algorithm based on the new homotopy perturbation transform meth...
AbstractIn this paper, we present a reliable algorithm based on the new homotopy perturbation transf...
The present paper aims to investigate the numerical solutions of the seventh order Caputo fractional...
In this paper, a new approximate solution of time-fractional order multi-dimensional Navier–Stokes e...
In this article, we introduce a new technique to create a series solution to the time-fractional Nav...
In this study, numerical results of a fractional-order multi-dimensional model of the Navier–Stokes ...
In this paper, the Elzaki transform decomposition method is implemented to solve the time-fractional...
The idea proposed in this work is to extend the ZZ transform method to resolve the nonlinear fractio...
In this paper, we introduce a modified method which is constructed by mixing the residual power seri...
The main features of scientific efforts in physics and engineering are the development of models for...
In this article, we study the analytical solution of time-fractional Navier-Stokes equation based on...
In this paper, numerical solution of fractional order Navier-Stokes equations in unsteady viscous fl...
In this manuscript, a semianalytical solution of the time-fractional Navier-Stokes equation under Ca...
In this paper we will use the residual power series (RPS) method to generate the solution of the non...
This paper witnesses the coupling of two basic transforms: the He-Laplace transform (HLT) which is a...
In this paper, we present a reliable algorithm based on the new homotopy perturbation transform meth...
AbstractIn this paper, we present a reliable algorithm based on the new homotopy perturbation transf...
The present paper aims to investigate the numerical solutions of the seventh order Caputo fractional...
In this paper, a new approximate solution of time-fractional order multi-dimensional Navier–Stokes e...
In this article, we introduce a new technique to create a series solution to the time-fractional Nav...
In this study, numerical results of a fractional-order multi-dimensional model of the Navier–Stokes ...
In this paper, the Elzaki transform decomposition method is implemented to solve the time-fractional...
The idea proposed in this work is to extend the ZZ transform method to resolve the nonlinear fractio...
In this paper, we introduce a modified method which is constructed by mixing the residual power seri...
The main features of scientific efforts in physics and engineering are the development of models for...