Double-diffusive transport and thermodynamic analysis of a magnetic microreactor with non-Newtonian biofuel flow
Double-diffusive transport and thermodynamic analysis of a magnetic microreactor with non-Newtonian biofuel flow
Magnetic microfuel-reforming is a promising method of biofuel processing in diesel engines. However, the complex interactions amongst the non-Newtonian biofuel flow, magnetic field and reactor have hindered understanding of their influences upon the transport phenomena in the system. To resolve this issue, the transport of heat and mass in a porous microreactor containing a Casson rheological fluid and subject to a magnetic field is investigated analytically. The system is assumed to host a homogenous and uniformly distributed endothermic/exothermic chemical reaction. Two-dimensional analytical solutions are developed for the temperature and concentration fields as well as the Nusselt number and local entropy generations, and the results are rigorously validated. It is demonstrated that changes in the non-Newtonian characteristics of the fluid and altering the magnetic and thermal radiation properties can lead to bifurcation of temperature gradient on the surface of the porous medium. The general behaviour of such bifurcation is dominated by the exothermicity (or endothermicity) of the chemical reaction in the fluid phase. It is also shown that variations in the Casson fluid parameter and changes in the intensity and incident angle of the magnetic field can modify the Nusselt number considerably. The extent of these modifications is found to be heavily dependent upon the wall thickness and diminishes as the walls become thicker. Further, the total entropy generation is shown to be highly sensitive to the wall thickness and increases by intensifying the magnetic field, provided that the microreactor walls are thin.
917-941
Saeed, Ali
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Karimi, Nader
620646d6-27c9-4e1e-948f-f23e4a1e773a
Hunt, Graeme
f8699a0e-ceca-4d8a-9898-115f3b9abfde
Torabi, Mohsen
2db5d46a-ab62-402a-b64e-e0f07edfee18
Mehdizadeh, Amirfarhang
e6f27402-32a9-41c8-a937-c2b035df6985
1 May 2020
Saeed, Ali
d1217de3-92c3-4b0b-b53c-1d55f27dddff
Karimi, Nader
620646d6-27c9-4e1e-948f-f23e4a1e773a
Hunt, Graeme
f8699a0e-ceca-4d8a-9898-115f3b9abfde
Torabi, Mohsen
2db5d46a-ab62-402a-b64e-e0f07edfee18
Mehdizadeh, Amirfarhang
e6f27402-32a9-41c8-a937-c2b035df6985
Saeed, Ali, Karimi, Nader, Hunt, Graeme, Torabi, Mohsen and Mehdizadeh, Amirfarhang
(2020)
Double-diffusive transport and thermodynamic analysis of a magnetic microreactor with non-Newtonian biofuel flow.
Journal of Thermal Analysis and Calorimetry, 140 (3), .
(doi:10.1007/s10973-019-08629-3).
Abstract
Magnetic microfuel-reforming is a promising method of biofuel processing in diesel engines. However, the complex interactions amongst the non-Newtonian biofuel flow, magnetic field and reactor have hindered understanding of their influences upon the transport phenomena in the system. To resolve this issue, the transport of heat and mass in a porous microreactor containing a Casson rheological fluid and subject to a magnetic field is investigated analytically. The system is assumed to host a homogenous and uniformly distributed endothermic/exothermic chemical reaction. Two-dimensional analytical solutions are developed for the temperature and concentration fields as well as the Nusselt number and local entropy generations, and the results are rigorously validated. It is demonstrated that changes in the non-Newtonian characteristics of the fluid and altering the magnetic and thermal radiation properties can lead to bifurcation of temperature gradient on the surface of the porous medium. The general behaviour of such bifurcation is dominated by the exothermicity (or endothermicity) of the chemical reaction in the fluid phase. It is also shown that variations in the Casson fluid parameter and changes in the intensity and incident angle of the magnetic field can modify the Nusselt number considerably. The extent of these modifications is found to be heavily dependent upon the wall thickness and diminishes as the walls become thicker. Further, the total entropy generation is shown to be highly sensitive to the wall thickness and increases by intensifying the magnetic field, provided that the microreactor walls are thin.
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Published date: 1 May 2020
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Local EPrints ID: 509079
URI: http://eprints.soton.ac.uk/id/eprint/509079
ISSN: 1388-6150
PURE UUID: 35238795-6628-43a2-8a72-7d4a0363eb53
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Date deposited: 10 Feb 2026 18:11
Last modified: 11 Feb 2026 03:18
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Author:
Ali Saeed
Author:
Nader Karimi
Author:
Graeme Hunt
Author:
Mohsen Torabi
Author:
Amirfarhang Mehdizadeh
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