%0 Journal Article
%T The Effects of an Inclined Magnetic Field, Brownian Motion, and Thermophoresis on the Flow of Electrically Conducting and Chemically Reacting Casson Nanofluids Using Soret-Dufour Mechanisms
%A Toyin Wasiu Akaje
%A Bakai Ishola Olajuwon
%J Advances in Nanoparticles
%P 55-71
%@ 2169-0529
%D 2022
%I Scientific Research Publishing
%R 10.4236/anp.2022.112005
%X This research explored the effects of an angled
magnetic field, Brownian motion, and thermophoresis on the flow of an
electrically conducting and chem<span>ically
reacting Casson nanofluid under the influence of the Soret-Dufour me</span>chanism.
A set of partial differential equations is generated by the flow mode. The
governing partial differential equations are solved numerically using the
spectral collocation method after being transformed to self-similar forms. The
effect of various fluid parameters on the velocity profile, temperature
profile, <span>and nanoparticle concentration is
addressed. A quantitative agreement is </span><span>observed
when previous findings are compared to the current results. The ski</span>n <span>friction, local Nusselt number, and local Sherwood
number are also exam</span>ined, and the results are presented in the table.
This study discovered that the inclined magnetic field has a significant impact
on the flow of the electrically conducting fluid by delaying its mobility
within the boundary layer. The plastic dynamic viscosity, which acts as a
barrier to fluid flow, is shown to degenerate the fluid velocity when the Casson
parameter is increased. As a conse<span>quence,
the findings may be used to improve thermal science instruments an</span>d
increase industrial output.
%K Soret-Dufour Mechanism
%K Casson Nanofluid
%K Inclined Magnetic Field
%K Boundary Layer
%K Spectral Collocation Method
%U http://www.scirp.org/journal/PaperInformation.aspx?PaperID=117543