An Approximate Analytical Solution of the Navier-Stokes Equations Within Caputo Operator and Elzaki Transform Decomposition Method
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Date
2020
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Springer
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Abstract
In this article, a hybrid technique of Elzaki transformation and decomposition method is used to solve the Navier-Stokes equations with a Caputo fractional derivative. The numerical simulations and examples are presented to show the validity of the suggested method. The solutions are determined for the problems of both fractional and integer orders by a simple and straightforward procedure. The obtained results are shown and explained through graphs and tables. It is observed that the derived results are very close to the actual solutions of the problems. The fractional solutions are of special interest and have a strong relation with the solution at the integer order of the problems. The numerical examples in this paper are nonlinear and thus handle its solutions in a sophisticated manner. It is believed that this work will make it easy to study the nonlinear dynamics, arising in different areas of research and innovation. Therefore, the current method can be extended for the solution of other higher-order nonlinear problems.
Description
Hajira Hajira/0000-0002-1220-4276; Arif, Muhammad/0000-0003-1484-7643; Khan, Adnan/0000-0001-7845-609X; Khan, Hassan/0000-0001-6417-1181
Keywords
Elzaki Transformation, Adomian Decomposition Method, Navier–, Stokes Equations, Caputo Operator, Decomposition method (queueing theory), FOS: Mechanical engineering, Biochemistry, Gene, Convergence Analysis of Iterative Methods for Nonlinear Equations, Differential equation, Engineering, Numerical Analysis, Applied Mathematics, Physics, Partial differential equation, Derivative-Free Methods, Discrete mathematics, Mechanical engineering, FOS: Philosophy, ethics and religion, Programming language, Fractional Derivatives, Chemistry, Modeling and Simulation, Physical Sciences, Transformation (genetics), Iterative Methods, Fractional Differential Equations, Caputo operator, Epistemology, Operator (biology), Theory and Applications of Fractional Differential Equations, Mathematical analysis, Quantum mechanics, Navier–Stokes equations, QA1-939, FOS: Mathematics, Work (physics), Anomalous Diffusion Modeling and Analysis, Fractional calculus, Applied mathematics, Computer science, Elzaki transformation, Philosophy, Nonlinear system, Simple (philosophy), Repressor, Adomian decomposition method, Fractional Calculus, Integer (computer science), Transcription factor, Mathematics, Ordinary differential equation, Fractional derivatives and integrals, Integro-partial differential equations, Numerical methods for integral equations, Fractional partial differential equations, Navier-Stokes equations, Spectral, collocation and related methods for initial value and initial-boundary value problems involving PDEs
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Fields of Science
01 natural sciences, 0101 mathematics
Citation
Khan, Hassan;...et.al. "An approximate analytical solution of the Navier–Stokes equations within Caputo operator and Elzaki transform decomposition method", Advances in Difference Equations, Vol.2020, No.1.
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Q1
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OpenCitations Citation Count
28
Source
Advances in Difference Equations
Volume
2020
Issue
1
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CrossRef : 17
Scopus : 48
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