Mass transfer phenomena of MHD nanofluid with chemical reaction with base fluids water and kerosene

K. Saritha; T. Gandhimathi; M. Rameshkumar

doi:10.26637/MJM0802/0059

Abstract

Mass Transfer of MHD nanofluid flow phenomena with chemical reaction and prescribed mass flux is analyzed. This work is composed of 5 nanoparticles such as $\mathrm{Cu}, \mathrm{Ag}, \mathrm{Al}, \mathrm{Al}_2 \mathrm{O}_3$ and $\mathrm{TiO}_2$ and two base fluids water and kerosene. Momentum and concentration equations are solved using the Runge-Kutta-Fehlberg method of numerical technique. The flow analysis and concentration of nanofluid $\mathrm{Cu}$-water and $\mathrm{Cu}$-kerosene by the effect of magnetic parameter, nanoparticle volume fraction, permeability parameter, suction parameter, Schmidt number and chemical reaction parameter is analyzed. The Sherwood number of various nanofluids are tabulated and analyzed. Comparison analysis was performed with the data recorded previously. It is concluded that the rate of mass transfer of kerosene based nanofluids is lower than that of water based nanofluids.

Keywords:

Porous surface, Nanofluid, Water and Kerosene Chemical reaction, Mass flux

Mathematics Subject Classification:

Mathematics

Authors Imprint References Funding Related Articles Downloads

K. Saritha Department of Mathematics, P.A College of Engineering and Technology, Pollachi-642002, Tamil Nadu, India. https://orcid.org/0000-0002-5859-8418
T. Gandhimathi Department of Mathematics, P.A College of Engineering and Technology, Pollachi-642002, Tamil Nadu, India.
M. Rameshkumar Department of Mathematics, P.A College of Engineering and Technology, Pollachi-642002, Tamil Nadu, India.

Pages: 668-673
Date Published: 01-04-2020
Vol. 8 No. 02 (2020): Malaya Journal of Matematik (MJM)

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