The three-dimensional laminar and steady boundary layer flow of an electrically nonconducting and incompressible magnetic fluid, with low Curie temperature and moderate saturation magnetization, over an elastic stretching sheet, is numerically studied. The fluid is subject to the magnetic field generated by an infinitely long, straight wire, carrying an electric current. The magnetic fluid far from the surface is at rest and at temperature greater of that of the sheet. It is also assumed that the magnetization of the fluid varies with the magnetic field strength $H$ and the temperature $T$. The numerical solution of the coupled and nonlinear system of ordinary differential equations, resulting after the introduction of appropriate nondimensional variables, with its boundary conditions, describing the problem under consideration, is obtained by an efficient numerical technique based on the common finite difference method. Numerical calculations are carried out for the case of a representative water-based magnetic fluid and for specific values of the dimensionless parameters entering into the problem, and the obtained results are presented graphically for these values of the parameters. The analysis of these results showed that there is an interaction between the motions of the fluid, which are induced by the stretching surface and by the action of the magnetic field, and the flow field is noticeably affected by the variations in the magnetic interaction parameter $\beta $. The important results of the present analysis are summarized in Sec. 6.

Skip Nav Destination

tzirtzi@iconography.gr

nikaf@math.upatras.gr

Close
Sign In or Register for Account

Article navigation

January 2010

Research Papers

# Three-Dimensional Magnetic Fluid Boundary Layer Flow Over a Linearly Stretching Sheet

E. E. Tzirtzilakis,

E. E. Tzirtzilakis

Assistant Professor

Department of Mechanical Engineering and Water Resources,

tzirtzi@iconography.gr
Technological Educational Institute of Messolonghi

, 30 200 Messolonghi, Greece
Search for other works by this author on:

N. G. Kafoussias

N. G. Kafoussias

Professor

Department of Mathematics, Section of Applied Analysis,

nikaf@math.upatras.gr
University of Patras

, 26 500 Patras, Greece
Search for other works by this author on:

E. E. Tzirtzilakis
Assistant Professor

Department of Mechanical Engineering and Water Resources,

Technological Educational Institute of Messolonghi

, 30 200 Messolonghi, Greecetzirtzi@iconography.gr

N. G. Kafoussias
Professor

Department of Mathematics, Section of Applied Analysis,

University of Patras

, 26 500 Patras, Greecenikaf@math.upatras.gr

*J. Heat Transfer*. Jan 2010, 132(1): 011702 (8 pages)

**Published Online:**October 26, 2009

Article history

Received:

September 18, 2008

Revised:

June 23, 2009

Published:

October 26, 2009

Citation

Tzirtzilakis, E. E., and Kafoussias, N. G. (October 26, 2009). "Three-Dimensional Magnetic Fluid Boundary Layer Flow Over a Linearly Stretching Sheet." ASME. *J. Heat Transfer*. January 2010; 132(1): 011702. https://doi.org/10.1115/1.3194765

Download citation file:

- Ris (Zotero)
- Reference Manager
- EasyBib
- Bookends
- Mendeley
- Papers
- EndNote
- RefWorks
- BibTex
- ProCite
- Medlars

Close

#### Sign In

### Get Email Alerts

### Cited By

### Related Articles

Numerical Prediction of Cavitating MHD Flow of Electrically Conducting Magnetic Fluid in a Converging-Diverging Nozzle

J. Appl. Mech (November,2004)

Effect of Velocity and Temperature Boundary Conditions on Convective Instability in a Ferrofluid Layer

J. Heat Transfer (October,2008)

Stability of the Boiling Two-Phase Flow of a Magnetic Fluid

J. Appl. Mech (November,2007)

Effects of a Magnetic Modulation on the Stability of a Magnetic Liquid Layer Heated From Above

J. Heat Transfer (June,2001)

### Related Proceedings Papers

### Related Chapters

Introduction

Introduction to Finite Element, Boundary Element, and Meshless Methods: With Applications to Heat Transfer and Fluid Flow

An Improved Power Diode Model Based on Finite Difference Method

International Conference on Advanced Computer Theory and Engineering (ICACTE 2009)

Approximate Analysis of Plates

Design of Plate and Shell Structures