In this article, an attempt has been made to study the behavior of non-Newtonian viscoelastic model of a Williamson fluid flow problem containing nanoparticles and is assumed to be flowing over a stretching sheet stretched along its surface in both directions with the same constant surface stretching velocity. The boundary layer governing equations of the conservation of mass, conservation of linear momentum and the energy are first modeled into a set of nonlinear coupled partial differential equations along with the appropriate boundary conditions. A numerical study of impact of nanofluid flow over a stretching sheet is tabulated. The basic equations of Williamson fluid are modeled with the help of Navier-Stokes equations for momentum and heat transfer. With the assistance of appropriate similarity transformations these pair of PEDs is transformed into up-to-date system of coupled nonlinear ODEs. These transformed systems of equations are evaluated numerically with the assistance of shooting method using forth order. The dominant physical properties for system of equations of the model that is wall shear stress, and the coefficient of skin friction are acquired. The behavior of nondimensional velocity and thermal flow profiles are discussed for the important involved dimensionless parameters like the Williamson fluid parameter and the nanoparticles volume fraction through tables and graphs.
| Published in | International Journal of Systems Engineering (Volume 5, Issue 1) |
| DOI | 10.11648/j.ijse.20210501.12 |
| Page(s) | 13-17 |
| Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
| Copyright |
Copyright © The Author(s), 2021. Published by Science Publishing Group |
Boundary Layer Flow, Williamson Fluid, Nanoparticles, Stretching Sheet
| [1] | Williamson, R. V., The flow of pseudoplastic materials. Industrial & Engineering Chemistry Research, 21, No. 11, 1108 (1929). |
| [2] | Dapra and Scarpi, G., Perturbation solution for pulsatile flow of a non-Newtonian Williamson fluid in a rock fracture. International Journal of Rock Mechanics and Mining Sciences, 44, 271 (2007). |
| [3] | S. U. S. Choi, “Enhancing thermal conductivity of fluids with nanoparticle,” in Developments and Applications of Non-Newtonian Flows, D. A. Siginer and H. P. Wang, Eds., vol. 231, pp. 99–105, ASME, New York, NY, USA. (1995). |
| [4] | Crane LJ. Flow past a stretching plate. Zeitschrift für angewandte Mathematik und Physik (Z AMP). 197 0; 21(4): 645- 647. |
| [5] | Nadeem, S. and Akbar, N. S., Numerical solutions of peristaltic flow of Williamson fluid with radially varying MHD in an endoscope. International Journal for Numerical Methods in Fluids, 66, No. 2, 212 (2010). |
| [6] | Vasudev, C., Rao, U. R., Reddy, M. V. S. and Rao, G. P., Peristaltic pumping of Williamson fluid through a porous medium in a horizontal channel with heat transfer. American Journal of Scientific and Industrial Research, 1, No. 3, 656 (2010). |
| [7] | Cramer, S. D. and Marchello, J. M., Numerical evaluation of models describing non-Newtonian behavior. American Institute of Chemical Engineers Journal, 14, 980 (1968). |
| [8] | Khan WA, Pop I. Boundary-layer flow of a nanofluid past a stretching sheet. International Journal of Heat and Mass Transfer. (2010) 53 (11): 2477-2483. |
| [9] | Makinde OD, Aziz A. Boundary layer flow of a nanofluid past a stretching sheet with a convective boundary condition. International Journal of Thermal Sciences. 2011; 50 (7): 1326-1332. |
| [10] | Sakiadis, B. C., Boundary layer behavior on continuous solid flat surfaces. American Institute of Chemical Engineers Journal, 7, 26 (1961). |
| [11] | Tsou, F. K., Sparrow, E. M. and Goldstein, R. J., Flow And heat transfer in the boundary layer on a continuous moving surface. International Journal of Heat and Mass Transfer, 10, 219 (1967). |
| [12] | Erickson, L. E., Fan, L. T. and Fox, V. G., Heat and mass transfer in the laminar boundary layer flow of a moving flat surface with constant surface velocity and temperature focusing on the effects of suction/injection. Industrial & Engineering Chemistry Research, 5, 19 (1966). |
| [13] | Gupta, P. S. and Gupta, A. S., Heat and mass transfer on a stretching sheet with suction or blowing. Canadian Journal of Chemical Engineering, 55, No. 6, 744 (1977). |
| [14] | Ishak, A., Nazar, R. and Pop, I., Heat Transfer over a stretching surface with variable heat flux in micropolar fluids. Physics Letters A, 372, No. 5, 559 (2008). |
| [15] | Nadeem, S., Hussain, A. and Khan, M., HAM solutions for boundary layer flow in the region of the stagnation point towards a stretching sheet. Communications in Nonlinear Science and Numerical Simulation, 15, No. 3, 475 (2010). |
| [16] | S. Nadeem, Abdul Rehman, K. Vajravelu, Jinho Lee, Changhoon Lee, Axisymmetric stagnation flow of a micropolar nanofluid in a moving cylinder, Mathematical Problems in Engineering, Volume 2012, Article ID 378259. |
| [17] | Abdul Rehman, S. Nadeem, Mixed convection heat transfer in micropolar nanofluid over a vertical slender cylinder, Chin. Phy. Lett. 29 (12) (2012) 124701-5. |
| [18] | S. Nadeem, Abdul Rehman, Changhoon Lee, Jinho Lee, Boundary layer flow of second grade fluid in a cylinder with heat transfer, Mathematical Problems in Engineering, Volume 2012, Article ID 640289. |
| [19] | S. Nadeem, Abdul Rehman, Mohamed Ali, The boundary layer flow and heat transfer of a nanofluid over a vertical slender cylinder, J. NanoEngineering and NanoSystems (2012) 1-9. |
| [20] | S. Nadeem, Abdul Rehman, Axisymmetric stagnation flow of a nanofluid in a moving cylinder, Comp. Math. Mod. 24 (2) (2013) 293-306. |
| [21] | Abdul Rehman, S. Nadeem, M. Y. Malik, Stagnation flow of couple stress nanofluid over an exponentially stretching sheet through a porous medium, J. Power Tech. 93(2) (2013) 122-132. |
| [22] | Abdul Rehman, S. Nadeem, M. Y. Malik, Boundary layer stagnation-point flow of a third-grade fluid over an exponentially stretching sheet, Braz. J. Che. Eng. 30 (3) (2013) 611-618. |
| [23] | Abdul Rehman, S. Nadeem, Heat transfer analysis of the boundary layer flow over a vertical exponentially stretching cylinder, Global J. Sci. Fron. Res. 13(11) (2013) 73-85. |
| [24] | M. Y. Malik, M. Naseer, S. Nadeem, Abdul Rehman, The boundary layer flow of Casson nanofluid over a vertical exponentially stretching cylinder, Appl. NanoSci. DOI: 10.1007/s13204-012-0267-0 |
| [25] | Abdul Rehman, S. Nadeem, S. Iqbal, M. Y. Malik, M. Naseer, Nanoparticle effect over the boundary layer flow over an exponentially stretching cylinder, J. NanoEngineering and NanoSystems (2014) 1-6. |
| [26] | M. Y. Malik, M. Naseer, S. Nadeem, Abdul Rehman, The boundary layer flow of hyperbolic tangent fluid over a vertical exponentially stretching cylinder, Alexandria Eng. J., 53 (2014) 747-750. |
| [27] | M. Y. Malik, M. Naseer, Abdul Rehman, Numerical study of convective heat transfer on the Power Law fluid over a vertical exponentially stretching cylinder, App Comp Math, 4(5), (2015) 346-350. |
| [28] | Abdul Rehman, R. Bazai, S. Achakzai, S. Iqbal, M. Naseer, Boundary Layer Flow and Heat Transfer of Micropolar Fluid over a Vertical Exponentially Stretched Cylinder, App Comp Math, 4(6) (2015) 424-430. |
| [29] | Abdul Rehman, G. Farooq, I. Ahmed, M. Naseer, M. Zulfiqar, Boundary Layer Stagnation-Point Flow of Second Grade Fluid over an Exponentially Stretching Sheet, American J App Math Stat, 3(6) (2015) 211-219. |
| [30] | Abdul Rehmana, S. Achakzai, S. Nadeem, S. Iqbal, Stagnation point flow of Eyring Powell fluid in a vertical cylinder with heat transfer, Journal of Power Technologies 96 (1) (2016) 57–62. |
| [31] | Abdul Rehman, Saleem Iqbal, Syed Mohsin Raza, Axisymmetric Stagnation Flow of a Micropolar Fluid in a Moving Cylinder: An Analytical Solution, Fluid Mechanics, 2(1) (2016) 1-7. |
| [32] | Naheeda Iftikhar, Abdul Rehman, Peristaltic flow of an Eyring Prandtl fluid in a diverging tube with heat and mass transfer, International Journal of Heat and Mass Transfer 111 (2017) 667–676. |
| [33] | Abdul Rehman, Naveed Sheikh, Boundary Layer Stagnation-Point Flow of Micropolar Fluid over an Exponentially Stretching Sheet, International Journal of Fluid Mechanics & Thermal Sciences, 2017; 3 (3): 25-31. |
| [34] | Haroon Rasheed, Abdul Rehman, Naveed Sheikh, Saleem Iqbal, MHD Boundary Layer Flow of Nanofluid over a Continuously Moving Stretching Surface, Applied and Computational Mathematics, 2017; 6 (6): 265-270. |
| [35] | Najeeb Alam Khan, Umair Bin Saeed, Faqiha Sultan, Saif Ullah, and Abdul Rehman, Study of velocity and temperature distributions in boundary layer flow of fourth grade fluid over an exponential stretching sheet, AIP ADVANCES 8, 025011 (2018). |
| [36] | Naheeda Iftikhar, Abdul Rehman, Hina Sadaf, Muhammad Najam Khan, Impact of wall properties on the peristaltic flow of Cu-water nano fluid in a non-uniform inclined tube, International Journal of Heat and Mass Transfer 125 (2018) 772–779. |
| [37] | Naheeda Iftikhar, Abdul Rehman and Muhammad Najam Khan, Features of Convective heat transfer on MHD peristaltic movement of Williamson fluid with the presence of Joule heating, IOP Conf. Series: Materials Science and Engineering 414 (2018) 012010. |
| [38] | Amina Panezai, Abdul Rehman, Naveed Sheikh, Saleem Iqbal, Israr Ahmed, Manzoor Iqbal, Muhammad Zulfiqar, Mixed Convective Magnetohydrodynamic Heat Transfer Flow of Williamson Fluid Over a Porous Wedge, American Journal of Mathematical and Computer Modelling, 4(3) (2019) 66-73. |
| [39] | N. Ambreen, A. Rehman, N. Sheikh, S. Iqbal, M. Zulfqar, Boundary-Layer Flow and Heat Transfer over a Rotating Porous Disk in a Non-Newtonian Williamson Nanofluid, Indian Journal of Science and Technology, 12(38) (2019) 1-8. |
| [40] | Naheeda Iftikhar, Abdul Rehman, Hina Sadaf, and Saleem Iqbal, Study of Al2O3/copper–water nanoparticle shape, slip effects, and heat transfer on steady physiological delivery of MHD hybrid nanofluid, Canadian Journal of Physics, 97 (12) (2019) 1239-1252. |
APA Style
Farah Deba, Abdul Rehman, Zahida Khan, Saleem Iqbal, Naveed Sheikh. (2021). Flow of a Williamson Fluid over a Stretching Sheet Containing Nanoparticles. International Journal of Systems Engineering, 5(1), 13-17. https://doi.org/10.11648/j.ijse.20210501.12
ACS Style
Farah Deba; Abdul Rehman; Zahida Khan; Saleem Iqbal; Naveed Sheikh. Flow of a Williamson Fluid over a Stretching Sheet Containing Nanoparticles. Int. J. Syst. Eng. 2021, 5(1), 13-17. doi: 10.11648/j.ijse.20210501.12
AMA Style
Farah Deba, Abdul Rehman, Zahida Khan, Saleem Iqbal, Naveed Sheikh. Flow of a Williamson Fluid over a Stretching Sheet Containing Nanoparticles. Int J Syst Eng. 2021;5(1):13-17. doi: 10.11648/j.ijse.20210501.12
Share This Article
Twitter
Linked In
Facebook
Copy
Download@article{10.11648/j.ijse.20210501.12,
author = {Farah Deba and Abdul Rehman and Zahida Khan and Saleem Iqbal and Naveed Sheikh},
title = {Flow of a Williamson Fluid over a Stretching Sheet Containing Nanoparticles},
journal = {International Journal of Systems Engineering},
volume = {5},
number = {1},
pages = {13-17},
doi = {10.11648/j.ijse.20210501.12},
url = {https://doi.org/10.11648/j.ijse.20210501.12},
eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ijse.20210501.12},
abstract = {In this article, an attempt has been made to study the behavior of non-Newtonian viscoelastic model of a Williamson fluid flow problem containing nanoparticles and is assumed to be flowing over a stretching sheet stretched along its surface in both directions with the same constant surface stretching velocity. The boundary layer governing equations of the conservation of mass, conservation of linear momentum and the energy are first modeled into a set of nonlinear coupled partial differential equations along with the appropriate boundary conditions. A numerical study of impact of nanofluid flow over a stretching sheet is tabulated. The basic equations of Williamson fluid are modeled with the help of Navier-Stokes equations for momentum and heat transfer. With the assistance of appropriate similarity transformations these pair of PEDs is transformed into up-to-date system of coupled nonlinear ODEs. These transformed systems of equations are evaluated numerically with the assistance of shooting method using forth order. The dominant physical properties for system of equations of the model that is wall shear stress, and the coefficient of skin friction are acquired. The behavior of nondimensional velocity and thermal flow profiles are discussed for the important involved dimensionless parameters like the Williamson fluid parameter and the nanoparticles volume fraction through tables and graphs.},
year = {2021}
}
TY - JOUR T1 - Flow of a Williamson Fluid over a Stretching Sheet Containing Nanoparticles AU - Farah Deba AU - Abdul Rehman AU - Zahida Khan AU - Saleem Iqbal AU - Naveed Sheikh Y1 - 2021/04/30 PY - 2021 N1 - https://doi.org/10.11648/j.ijse.20210501.12 DO - 10.11648/j.ijse.20210501.12 T2 - International Journal of Systems Engineering JF - International Journal of Systems Engineering JO - International Journal of Systems Engineering SP - 13 EP - 17 PB - Science Publishing Group SN - 2640-4230 UR - https://doi.org/10.11648/j.ijse.20210501.12 AB - In this article, an attempt has been made to study the behavior of non-Newtonian viscoelastic model of a Williamson fluid flow problem containing nanoparticles and is assumed to be flowing over a stretching sheet stretched along its surface in both directions with the same constant surface stretching velocity. The boundary layer governing equations of the conservation of mass, conservation of linear momentum and the energy are first modeled into a set of nonlinear coupled partial differential equations along with the appropriate boundary conditions. A numerical study of impact of nanofluid flow over a stretching sheet is tabulated. The basic equations of Williamson fluid are modeled with the help of Navier-Stokes equations for momentum and heat transfer. With the assistance of appropriate similarity transformations these pair of PEDs is transformed into up-to-date system of coupled nonlinear ODEs. These transformed systems of equations are evaluated numerically with the assistance of shooting method using forth order. The dominant physical properties for system of equations of the model that is wall shear stress, and the coefficient of skin friction are acquired. The behavior of nondimensional velocity and thermal flow profiles are discussed for the important involved dimensionless parameters like the Williamson fluid parameter and the nanoparticles volume fraction through tables and graphs. VL - 5 IS - 1 ER -
Information
Email: