Jing Wang1, M Ijaz Khan2, W A Khan3, S Z Abbas4, M Imran Khan5. 1. School of Information, Beijing Wuzi University, Beijing 101149, PR China. 2. Department of Mathematics, Quaid-I-Azam University, Islamabad 45320, Pakistan. Electronic address: mikhan@math.qau.edu.pk. 3. School of Mathematics and Statistics, Beijing Institute of Technology, Beijing 100081, PR China; Department of Mathematics, Mohi-ud-Din Islamic University, Nerian Sharif, 12010 Azad Kashmir, Pakistan. 4. School of Mathematics and Statistics, Beijing Institute of Technology, Beijing 100081, PR China; Department of Mathematics and Statistics, Hazara University, Mansehra 21300, Pakistan. 5. Heriot Watt University, Edinburgh Campus, Edinburgh EH14 4AS, United Kingdom.
Abstract
BACKGROUND: This study addresses the three-dimensional (3D) stagnation point flow of non-Newtonian material (Oldroyd-B) with magnetohydrodynamics. Furthermore, Ohmic heating and radiative flux are used in the modeling of energy expression. The surface is convectively heated. Equal strengths of diffusions for homogeneous and heterogeneous reactions are counted. Results are computed and presented graphically. Heat transfer rate is numerically discussed through table. METHOD: Here the nonlinear differential system first converted into ordinary differential equation through implementation of appropriate similarity variables. The obtained ordinary system is tackled through homotopy technique for convergent solutions. The outcomes are presented through different graphs and discussed in section six. OUTCOMES: The remarkable results of the present communication which is obtained from the semi analytical method i.e., "homotopy method" is summarized as (i) Opposite impact is noticed for velocity components i.e., (f'(ξ), g(ξ)) for rising fluid parameter and rotation parameter. (ii) The temperature is direct relation with Biot number and radiative variable. (iii) Heat transfer rate is more versus Biot number and radiation variable. (iv) The concentration field shows opposite impact versus homogeneous and heterogeneous parameters.
BACKGROUND: This study addresses the three-dimensional (3D) stagnation point flow of non-Newtonian material (Oldroyd-B) with magnetohydrodynamics. Furthermore, Ohmic heating and radiative flux are used in the modeling of energy expression. The surface is convectively heated. Equal strengths of diffusions for homogeneous and heterogeneous reactions are counted. Results are computed and presented graphically. Heat transfer rate is numerically discussed through table. METHOD: Here the nonlinear differential system first converted into ordinary differential equation through implementation of appropriate similarity variables. The obtained ordinary system is tackled through homotopy technique for convergent solutions. The outcomes are presented through different graphs and discussed in section six. OUTCOMES: The remarkable results of the present communication which is obtained from the semi analytical method i.e., "homotopy method" is summarized as (i) Opposite impact is noticed for velocity components i.e., (f'(ξ), g(ξ)) for rising fluid parameter and rotation parameter. (ii) The temperature is direct relation with Biot number and radiative variable. (iii) Heat transfer rate is more versus Biot number and radiation variable. (iv) The concentration field shows opposite impact versus homogeneous and heterogeneous parameters.
Authors: Ammar I Alsabery; Tahar Tayebi; Hakim T Kadhim; Mohammad Ghalambaz; Ishak Hashim; Ali J Chamkha Journal: J Adv Res Date: 2020-09-28 Impact factor: 10.479