On dispersion of solute in a hydromagnetic flow through a channel subject to asymmetric wall temperature and slip velocity

With the influence of asymmetric wall temperature and inclined magnetic field under a constant pressure gradient, the present study explores the transport process of solute in a magneto-hydrodynamics (MHD), viscous, incompressible, electrically conducting fluid through a porous channel. The coupled...

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Published inInternational journal of thermal sciences Vol. 215; p. 109951
Main Authors Das, Susmita, Mazumder, Bijoy Singha, Mondal, Kajal Kumar
Format Journal Article
LanguageEnglish
Published Elsevier Masson SAS 01.09.2025
Subjects
Asymmetric wall temperature
Inclined magnetic field
Method of moments
Piece-wise uniform mesh
Porous medium
Slip velocity
Asymmetric wall temperature
Slip velocity
Method of moments
Inclined magnetic field
Porous medium
Piece-wise uniform mesh
Online AccessGet full text
ISSN1290-0729
DOI10.1016/j.ijthermalsci.2025.109951

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Abstract With the influence of asymmetric wall temperature and inclined magnetic field under a constant pressure gradient, the present study explores the transport process of solute in a magneto-hydrodynamics (MHD), viscous, incompressible, electrically conducting fluid through a porous channel. The coupled heat and velocity equations are solved to obtain the explicit expressions for the temperature and velocity profiles. The slip velocity has been taken at the lower wall of the channel and the first order boundary absorption is applied at both the channel walls. Aris’s moment method is employed to obtain the first four central moments and the governing time-dependent advection-diffusion equation is solved, using an implicit finite-difference technique. The axial distribution of mean concentration of the solute is determined by the Hermite polynomial representation. For the first time, the various dispersion characteristics are observed for various parameters, such as the absorption parameter (β), angle of inclined magnetic field (α), Prandtl number (Pr), Hartmann number (M), suction Reynolds number (R), injection Reynolds number (R′), Darcy number (Dn), Grashof number (Gr), Navier slip parameter (γ), thermal radiation parameter (δ) and dispersion time (t), simultaneously. It is prominent that when γ increases from 0.1 to 0.2, the dispersion of solute increases 28.68% and when it increases from 0.2 to 0.3, Da increases by 22.75%. Conversely, when δ increases from 1 to 2, the dispersion of solute enhances more rapidly by 154.95% and when δ rises from 2 to 3, Da increases 39.33%. It is significant to note that, the amplitude of the mean concentration Cm(x,t) reduces as γ, Gr and Pr enhances. On the other hand, the amplitude of the mean concentration rises as α and M reduces. Both experimental and numerical validations are performed for the present work with the existing literature and an excellent agreement is achieved. For experimental validation, a combination of an artanh transformation and a piece-wise uniform mesh is utilized. Also, the two dimensional distribution of mean concentration is obtained analytically for various values of γ, Gr, Pr and δ. The obtained results from the current study are helpful for purification of crude oil, to understand the various hemodynamic conditions and for separation of matter from fluids etc. •To explore the nature of temperature and velocity profiles.•To investigate the combined effects of various flow parameters, on the transport process of solute through the channel with asymmetric wall temperature.•To validate the present numerical scheme with the experimental results.•To estimate the two-dimensional concentration distribution of solute.
AbstractList With the influence of asymmetric wall temperature and inclined magnetic field under a constant pressure gradient, the present study explores the transport process of solute in a magneto-hydrodynamics (MHD), viscous, incompressible, electrically conducting fluid through a porous channel. The coupled heat and velocity equations are solved to obtain the explicit expressions for the temperature and velocity profiles. The slip velocity has been taken at the lower wall of the channel and the first order boundary absorption is applied at both the channel walls. Aris’s moment method is employed to obtain the first four central moments and the governing time-dependent advection-diffusion equation is solved, using an implicit finite-difference technique. The axial distribution of mean concentration of the solute is determined by the Hermite polynomial representation. For the first time, the various dispersion characteristics are observed for various parameters, such as the absorption parameter (β), angle of inclined magnetic field (α), Prandtl number (Pr), Hartmann number (M), suction Reynolds number (R), injection Reynolds number (R′), Darcy number (Dn), Grashof number (Gr), Navier slip parameter (γ), thermal radiation parameter (δ) and dispersion time (t), simultaneously. It is prominent that when γ increases from 0.1 to 0.2, the dispersion of solute increases 28.68% and when it increases from 0.2 to 0.3, Da increases by 22.75%. Conversely, when δ increases from 1 to 2, the dispersion of solute enhances more rapidly by 154.95% and when δ rises from 2 to 3, Da increases 39.33%. It is significant to note that, the amplitude of the mean concentration Cm(x,t) reduces as γ, Gr and Pr enhances. On the other hand, the amplitude of the mean concentration rises as α and M reduces. Both experimental and numerical validations are performed for the present work with the existing literature and an excellent agreement is achieved. For experimental validation, a combination of an artanh transformation and a piece-wise uniform mesh is utilized. Also, the two dimensional distribution of mean concentration is obtained analytically for various values of γ, Gr, Pr and δ. The obtained results from the current study are helpful for purification of crude oil, to understand the various hemodynamic conditions and for separation of matter from fluids etc. •To explore the nature of temperature and velocity profiles.•To investigate the combined effects of various flow parameters, on the transport process of solute through the channel with asymmetric wall temperature.•To validate the present numerical scheme with the experimental results.•To estimate the two-dimensional concentration distribution of solute.
ArticleNumber 109951
Author Das, Susmita
Mazumder, Bijoy Singha
Mondal, Kajal Kumar
Author_xml – sequence: 1
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  givenname: Bijoy Singha
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  givenname: Kajal Kumar
  surname: Mondal
  fullname: Mondal, Kajal Kumar
  email: kkmondol@yahoo.co.in
  organization: Department of Mathematics, Cooch Behar Panchanan Barma University, Cooch Behar 736101, India
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Keywords Asymmetric wall temperature
Slip velocity
Method of moments
Inclined magnetic field
Porous medium
Piece-wise uniform mesh
Language English
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Snippet With the influence of asymmetric wall temperature and inclined magnetic field under a constant pressure gradient, the present study explores the transport...
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StartPage 109951
SubjectTerms Asymmetric wall temperature
Inclined magnetic field
Method of moments
Piece-wise uniform mesh
Porous medium
Slip velocity
Title On dispersion of solute in a hydromagnetic flow through a channel subject to asymmetric wall temperature and slip velocity
URI https://dx.doi.org/10.1016/j.ijthermalsci.2025.109951
Volume 215
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