Numerical simulation of electroosmosis regulated peristaltic transport of Bingham nanofluid

•Nanoparticle phenomena has been highlighted.•Electroosmotic flow is considered of Bingham fluid.•Mathematical peristaltic flow on Bingham Nanofluid.•Walls are assumed to be flexible.•Exact and analytical solutions are presented. The effects of slip condition and Joule heating on the peristaltic flo...

Full description

Saved in:
Bibliographic Details
Published in:Computer methods and programs in biomedicine 2019-10, Vol.180, p.105005-105005, Article 105005
Main Authors: Tanveer, Anum, Khan, Mair, Salahuddin, T., Malik, M.Y.
Format: Article
Language:English
Subjects:
Bingham fluid
Convective conditions
Electroosmosis
Heat transfer
Hydrodynamics
Joule heating
Models, Statistical
Nanoparticles
Peristalsis - physiology
Rheology
Slip conditions
Solutions - chemistry
Thermal Conductivity
Wall properties
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•Nanoparticle phenomena has been highlighted.•Electroosmotic flow is considered of Bingham fluid.•Mathematical peristaltic flow on Bingham Nanofluid.•Walls are assumed to be flexible.•Exact and analytical solutions are presented. The effects of slip condition and Joule heating on the peristaltic flow of Bingham nanofluid are investigated. The flow is taken in a porous channel with elastic walls. Mathematical formulation is presented under the assumption of long wavelength and small Reynolds number. The transformed equations for the flow are solved to seek values for the nanoparticles velocity, concentration and temperature along the channel length. Graphs are plotted to evaluate the behavior of various physical parameters on flow quantities in both slip and no-slip cases. The main features of the physical parameters are highlighted on the inclined non uniform channel. The results show an increment in velocity with rise in inclination and porosity while it reduces with magnetic field. Moreover, nanofluid favors the heat transfer and decline the concentration.
ISSN:0169-2607
1872-7565
DOI:10.1016/j.cmpb.2019.105005