Robin and zero‐mass diffusion analysis for radiated unsteady flow of Maxwell nanofluid due to porous stretched regime: Analytical simulations-Reference-Cited by-同舟云学术

Robin and zero‐mass diffusion analysis for radiated unsteady flow of Maxwell nanofluid due to porous stretched regime: Analytical simulations

Published:2024-07-25 Issue:9 Volume:104 Page:
ISSN:0044-2267
Container-title:ZAMM - Journal of Applied Mathematics and Mechanics / Zeitschrift für Angewandte Mathematik und Mechanik
language:en
Short-container-title:Z Angew Math Mech

Author:

Ahmad Manzoor¹,Khan Sami Ullah²^ORCID,Bibi Qudsia¹,Taj Muhammad¹,Tlili Iskander³,Butt Faisal Mehmood⁴

Affiliation:

1. Department of Mathematics University of Azad Jammu & Kashmir Muzaffarabad Pakistan

2. Department of Mathematics Namal University Mianwali Pakistan

3. Department of Physics College of Science Al‐Zulfi Majmaah University Al‐Majmaah Saudi Arabia

4. Department of Electrical Engineering University of Azad Jammu & Kashmir Muzaffarabad Pakistan

Abstract

AbstractOwing to the multidisciplinary applications of nanomaterials, a wide range of research has been conducted on this topic recently. The aim of current research is to analyze the enhancement of heat transfer due to the unsteady flow of Maxwell nanofluid associated with the zero mass thermal constraints. The applications of the radiated phenomenon and magnetic force are contributed to the current flow problem. The analysis is subject to the implementation of Robin and zero‐mass diffusion constraints. A bidirectional moving porous surface endorsed the flow. The appropriate variables are taken for simplifying the system. The homotopy analysis method (HAM) is used to compute the solution procedure. The obtained results are confirmed with already performed studies. It has been observed that the temperature and nanoparticle concentration distributions decrease for higher unsteady parameter values.

Publisher

Wiley

Link

https://onlinelibrary.wiley.com/doi/pdf/10.1002/zamm.202300421

Reference39 articles.

1. The three-dimensional flow due to a stretching flat surface

2. Magnetohydrodynamic time-dependent three-dimensional flow of Maxwell fluid over a stretching surface through porous space with variable thermal conditions

3. Flow and heat transfer of magnetohydrodynamic three-dimensional Maxwell nanofluid over a permeable stretching/shrinking surface with convective boundary conditions

4. Unsteady flow of a Maxwell nanofluid over a stretching surface in the presence of magnetohydrodynamic and thermal radiation effects

5. Combined electrical MHD heat transfer thermal extrusion system using Maxwell fluid with radiative and viscous dissipation effects