Chemical Reaction Effects on the Flow of Titanium Dioxide–Water in a Mixed Convective Nanofluid along an Inclined Plate in a Porous Medium

An inclined plate is being approached by a mixed convective boundary layer nanofluid flow of titanium dioxide–water through a porous medium. A numerical analysis has been done to investigate the effects of chemical reactions on the considered nanofluid flow. With the aid of a system of governing par...

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Bibliographic Details
Published in:Advances in mathematical physics 2024-07, Vol.2024 (1)
Main Authors: Uddin, Md. Nasir, Chowdhury, Kakali, Mim, Jannatul Ferdows
Format: Article
Language:English
Subjects:
Aluminum
Boundary conditions
Boundary layers
Chemical reactions
Coefficient of friction
Copper
Flow characteristics
Fluid flow
Heat
Influence
Investigations
Magnetic fields
Mass transfer
Nanofluids
Nanoparticles
Nonlinear differential equations
Numerical analysis
Nusselt number
Oil recovery
Parameters
Partial differential equations
Porous media
Radiation
Runge-Kutta method
Schmidt number
Skin friction
Titanium
Titanium dioxide
Velocity
Viscosity
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Summary:An inclined plate is being approached by a mixed convective boundary layer nanofluid flow of titanium dioxide–water through a porous medium. A numerical analysis has been done to investigate the effects of chemical reactions on the considered nanofluid flow. With the aid of a system of governing partial differential equations, a set of nonlinear ordinary differential equations for taking into consideration nanofluid flow have been derived using appropriate matching transformations. The Runge–Kutta method, as well as the Nachtsheim and Swigert Shooting method, is applied to numerically resolve the group of subsequent nondimensionalized equations. The associated numerical result was then successfully compared with the available published literature in a few unique, limited circumstances. Based on the considered nanofluid flow characteristics for heat as well as mass transfer, the effects of the Schmidt number, the permeability, and the chemical reaction parameters of the titanium dioxide–water nanofluid flow have been examined, assessed, and presented for velocity in conjunction with the local skin friction coefficient, temperature in conjunction with the local Nusselt number, as well as concentration in conjunction with the local Sherwood number. Numerical results reveal that the local Sherwood number Sh , as well as the local Nusselt number Nu x , increase, whereas the local skin friction coefficient C f decreases due to the increase in the chemical reaction parameter K rp .
ISSN:1687-9120
1687-9139
DOI:10.1155/2024/6451978