Hybrid numerical approach of finite difference and asymptotic interpolation methods for non-newtonian fluids flow

Previous research in the mathematical and physics fields has used computational or empirical approaches to analyse fluid flow problems. Therefore, in this thesis a hybrid numerical approach for non-Newtonian third- and fourth-grade fluid flow problems using the finite difference method and the asymp...

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Main Author: Mahadi, Shafaruniza
Format: Thesis
Language:English
Published: 2022
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Online Access:http://eprints.utm.my/id/eprint/101898/1/ShafarunizaMahadiPFS2022_%20valet-20221101-141039.pdf.pdf
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spelling my.utm.1018982023-07-22T03:19:44Z http://eprints.utm.my/id/eprint/101898/ Hybrid numerical approach of finite difference and asymptotic interpolation methods for non-newtonian fluids flow Mahadi, Shafaruniza QA Mathematics Previous research in the mathematical and physics fields has used computational or empirical approaches to analyse fluid flow problems. Therefore, in this thesis a hybrid numerical approach for non-Newtonian third- and fourth-grade fluid flow problems using the finite difference method and the asymptotic interpolation method are presented. The hybrid method is important for finding accurate results as the size of the problem domain increases to infinity. The finite difference method is used to discretize the nonlinear partial differential equation into a linear system. An asymptotic interpolation method is used to estimate nodal value as the size of the domain tends to infinity. The algorithm is coded using the MATLAB program. A polynomial function that fits the hybrid solution is used to calculate the error of the equation. Theoretical error analysis using truncation error in the finite difference method, right-hand side perturbation linear system, and right perturbation theorem is conducted to determine the norm and range of errors. An implicit numerical scheme of modified fluid problems with an exact solution has been achieved by adding an extra term to the partial differential equation. The norm of error between the hybrid method and exact solution is less than the norm of error between the finite difference method and exact solution. The theory of stability for third-grade fluid is carried out, and the numerical scheme is stable provided that the condition of modulus of the amplifier holds. The hybrid method is used to solve the constant acceleration of an unsteady magnetohydrodynamic third-grade fluid in a rotating frame. The analyses show that the increment of the magnetic and rotating parameters decreases the speed of motion and thus the velocity. The velocity increases with an increase in time. The unsteady magnetohydrodynamic fourth-grade fluid problem in the rotating frame is investigated. Increasing the elastic parameters increases the velocity of the fluid. The problem of heat transfer for third-grade non-Newtonian fluid flow with magnetic effect is addressed. The temperature drops by increasing the Prandtl number. It is noted that increasing the Grashof number increases the temperature and velocity. The obtained results have shown that the hybrid method is consistent, stable, and converges to the solution. 2022 Thesis NonPeerReviewed application/pdf en http://eprints.utm.my/id/eprint/101898/1/ShafarunizaMahadiPFS2022_%20valet-20221101-141039.pdf.pdf Mahadi, Shafaruniza (2022) Hybrid numerical approach of finite difference and asymptotic interpolation methods for non-newtonian fluids flow. PhD thesis, Universiti Teknologi Malaysia. http://dms.library.utm.my:8080/vital/access/manager/Repository/vital:148943
institution Universiti Teknologi Malaysia
building UTM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Teknologi Malaysia
content_source UTM Institutional Repository
url_provider http://eprints.utm.my/
language English
topic QA Mathematics
spellingShingle QA Mathematics
Mahadi, Shafaruniza
Hybrid numerical approach of finite difference and asymptotic interpolation methods for non-newtonian fluids flow
description Previous research in the mathematical and physics fields has used computational or empirical approaches to analyse fluid flow problems. Therefore, in this thesis a hybrid numerical approach for non-Newtonian third- and fourth-grade fluid flow problems using the finite difference method and the asymptotic interpolation method are presented. The hybrid method is important for finding accurate results as the size of the problem domain increases to infinity. The finite difference method is used to discretize the nonlinear partial differential equation into a linear system. An asymptotic interpolation method is used to estimate nodal value as the size of the domain tends to infinity. The algorithm is coded using the MATLAB program. A polynomial function that fits the hybrid solution is used to calculate the error of the equation. Theoretical error analysis using truncation error in the finite difference method, right-hand side perturbation linear system, and right perturbation theorem is conducted to determine the norm and range of errors. An implicit numerical scheme of modified fluid problems with an exact solution has been achieved by adding an extra term to the partial differential equation. The norm of error between the hybrid method and exact solution is less than the norm of error between the finite difference method and exact solution. The theory of stability for third-grade fluid is carried out, and the numerical scheme is stable provided that the condition of modulus of the amplifier holds. The hybrid method is used to solve the constant acceleration of an unsteady magnetohydrodynamic third-grade fluid in a rotating frame. The analyses show that the increment of the magnetic and rotating parameters decreases the speed of motion and thus the velocity. The velocity increases with an increase in time. The unsteady magnetohydrodynamic fourth-grade fluid problem in the rotating frame is investigated. Increasing the elastic parameters increases the velocity of the fluid. The problem of heat transfer for third-grade non-Newtonian fluid flow with magnetic effect is addressed. The temperature drops by increasing the Prandtl number. It is noted that increasing the Grashof number increases the temperature and velocity. The obtained results have shown that the hybrid method is consistent, stable, and converges to the solution.
format Thesis
author Mahadi, Shafaruniza
author_facet Mahadi, Shafaruniza
author_sort Mahadi, Shafaruniza
title Hybrid numerical approach of finite difference and asymptotic interpolation methods for non-newtonian fluids flow
title_short Hybrid numerical approach of finite difference and asymptotic interpolation methods for non-newtonian fluids flow
title_full Hybrid numerical approach of finite difference and asymptotic interpolation methods for non-newtonian fluids flow
title_fullStr Hybrid numerical approach of finite difference and asymptotic interpolation methods for non-newtonian fluids flow
title_full_unstemmed Hybrid numerical approach of finite difference and asymptotic interpolation methods for non-newtonian fluids flow
title_sort hybrid numerical approach of finite difference and asymptotic interpolation methods for non-newtonian fluids flow
publishDate 2022
url http://eprints.utm.my/id/eprint/101898/1/ShafarunizaMahadiPFS2022_%20valet-20221101-141039.pdf.pdf
http://eprints.utm.my/id/eprint/101898/
http://dms.library.utm.my:8080/vital/access/manager/Repository/vital:148943
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score 13.214268