Mixed convection and thermodynamic irreversibilities in MHD nanofluid stagnation-point flows over a cylinder embedded in porous media
Mixed convection and thermodynamic irreversibilities in MHD nanofluid stagnation-point flows over a cylinder embedded in porous media
The impingement of CuO-water nanofluid flows upon a cylinder subject to a uniform magnetic field with constant surface temperature and embedded in porous media is investigated for the first time in literature. The surface of the cylinder can feature uniform or non-uniform mass transpiration and is hotter than the incoming nanofluid flow. The gravitational effects are taken into account and the three-dimensional governing equations of mixed convection in curved porous media, under magnetohydrodynamic effects, are reduced to those solvable by a finite difference scheme. Through varying a mixed convection parameter, the situations dominated by forced, mixed and free convection are examined systematically. The numerical solutions of these equations reveal the flow velocity and temperature fields as well as the Nusselt number and induced shear stress. These are then used to calculate the rate of entropy generation within the system by viscous and heat transfer irreversibilities. The results show that Nusselt number increases with increasing the concentration of nanoparticles, while it slightly deceases through intensifying the magnetic parameter. Non-uniform transpiration is shown to strongly affect the average rate of heat transfer. Importantly, it is demonstrated that the specific mode of heat convection can majorly influence the intensity of entropy generation and that the irreversibilities are much larger under natural convection compared to those in mixed and forced convection. Calculation of Bejan number shows that this is due to more pronounced relative contribution of viscous irreversibilities when free convection effects dominate the mixed convection process.
489-506
Alizadeh, R.
8452d2d2-68c1-4a95-840f-8e19855799af
Karimi, N.
620646d6-27c9-4e1e-948f-f23e4a1e773a
Arjmandzadeh, R.
bcfb0f9f-0560-44f4-bbd4-77fb6c728cd8
Mehdizadeh, A.
48437b9b-1de9-45fc-8683-5069f384e5a9
2019
Alizadeh, R.
8452d2d2-68c1-4a95-840f-8e19855799af
Karimi, N.
620646d6-27c9-4e1e-948f-f23e4a1e773a
Arjmandzadeh, R.
bcfb0f9f-0560-44f4-bbd4-77fb6c728cd8
Mehdizadeh, A.
48437b9b-1de9-45fc-8683-5069f384e5a9
Alizadeh, R., Karimi, N., Arjmandzadeh, R. and Mehdizadeh, A.
(2019)
Mixed convection and thermodynamic irreversibilities in MHD nanofluid stagnation-point flows over a cylinder embedded in porous media.
Journal of Thermal Analysis and Calorimetry, 135, .
(doi:10.1007/s10973-018-7071-8).
Abstract
The impingement of CuO-water nanofluid flows upon a cylinder subject to a uniform magnetic field with constant surface temperature and embedded in porous media is investigated for the first time in literature. The surface of the cylinder can feature uniform or non-uniform mass transpiration and is hotter than the incoming nanofluid flow. The gravitational effects are taken into account and the three-dimensional governing equations of mixed convection in curved porous media, under magnetohydrodynamic effects, are reduced to those solvable by a finite difference scheme. Through varying a mixed convection parameter, the situations dominated by forced, mixed and free convection are examined systematically. The numerical solutions of these equations reveal the flow velocity and temperature fields as well as the Nusselt number and induced shear stress. These are then used to calculate the rate of entropy generation within the system by viscous and heat transfer irreversibilities. The results show that Nusselt number increases with increasing the concentration of nanoparticles, while it slightly deceases through intensifying the magnetic parameter. Non-uniform transpiration is shown to strongly affect the average rate of heat transfer. Importantly, it is demonstrated that the specific mode of heat convection can majorly influence the intensity of entropy generation and that the irreversibilities are much larger under natural convection compared to those in mixed and forced convection. Calculation of Bejan number shows that this is due to more pronounced relative contribution of viscous irreversibilities when free convection effects dominate the mixed convection process.
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s10973-018-7071-8
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Published date: 2019
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Local EPrints ID: 508907
URI: http://eprints.soton.ac.uk/id/eprint/508907
ISSN: 1388-6150
PURE UUID: dec78902-2702-4889-936d-bd954cac26eb
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Date deposited: 05 Feb 2026 17:55
Last modified: 06 Feb 2026 03:12
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Author:
R. Alizadeh
Author:
N. Karimi
Author:
R. Arjmandzadeh
Author:
A. Mehdizadeh
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