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Two-dimensional heat and mass transfer and thermodynamic analyses of porous microreactors with Soret and thermal radiation effects — an analytical approach

Two-dimensional heat and mass transfer and thermodynamic analyses of porous microreactors with Soret and thermal radiation effects — an analytical approach
Two-dimensional heat and mass transfer and thermodynamic analyses of porous microreactors with Soret and thermal radiation effects — an analytical approach
Transport of heat and mass and the thermodynamics of porous microreactors with thermal diffusion and radiation effects are investigated analytically. The examined configuration includes an axisymmetric, thick-wall microchannel with an iso-flux thermal boundary condition imposed on the external surfaces. The microchannel is filled with porous materials and accommodates a zeroth order homogenous chemical reaction. Internal radiative heat transfer is modelled in addition to heat convection and conduction, while the local thermal non-equilibrium approach is taken within the porous section of the system. The transport of species is coupled with that of heat via the inclusion of thermodiffusion or Soret effect. Two-dimensional heat and mass transfer differential equations are solved analytically. The results are subsequently used to predict the thermodynamic irreversibilities inside the reactor and a thorough analysis of local and total entropy generation rates is performed. Also, the changes in Nusselt number, calculated on the internal walls of the microreactor, versus various parameters are reported. It is shown that the radiation effects can impact the temperature of the solid phase of the porous medium and lead to alteration of Nusselt number. It is further observed that the transfer of mass is the main source of irreversibility in the system. The findings are of particular use for the design and analysis of the microreactors with homogenous chemical reactions and can be also used for the validation of computational models.
0255-2701
190-205
Hunt, G.
c61092e6-cb33-48f4-bfcc-08227d385bad
Torabi, M.
cca46013-f51a-4d5d-b8d0-7d54bcff33d0
Govone, L.
5d03c285-63cb-4fa4-bc6d-82284c793eee
Karimi, N.
620646d6-27c9-4e1e-948f-f23e4a1e773a
Mehdizadeh, A.
48437b9b-1de9-45fc-8683-5069f384e5a9
Hunt, G.
c61092e6-cb33-48f4-bfcc-08227d385bad
Torabi, M.
cca46013-f51a-4d5d-b8d0-7d54bcff33d0
Govone, L.
5d03c285-63cb-4fa4-bc6d-82284c793eee
Karimi, N.
620646d6-27c9-4e1e-948f-f23e4a1e773a
Mehdizadeh, A.
48437b9b-1de9-45fc-8683-5069f384e5a9

Hunt, G., Torabi, M., Govone, L., Karimi, N. and Mehdizadeh, A. (2018) Two-dimensional heat and mass transfer and thermodynamic analyses of porous microreactors with Soret and thermal radiation effects — an analytical approach. Chemical Engineering and Processing - Process Intensification, 126, 190-205. (doi:10.1016/j.cep.2018.02.025).

Record type: Article

Abstract

Transport of heat and mass and the thermodynamics of porous microreactors with thermal diffusion and radiation effects are investigated analytically. The examined configuration includes an axisymmetric, thick-wall microchannel with an iso-flux thermal boundary condition imposed on the external surfaces. The microchannel is filled with porous materials and accommodates a zeroth order homogenous chemical reaction. Internal radiative heat transfer is modelled in addition to heat convection and conduction, while the local thermal non-equilibrium approach is taken within the porous section of the system. The transport of species is coupled with that of heat via the inclusion of thermodiffusion or Soret effect. Two-dimensional heat and mass transfer differential equations are solved analytically. The results are subsequently used to predict the thermodynamic irreversibilities inside the reactor and a thorough analysis of local and total entropy generation rates is performed. Also, the changes in Nusselt number, calculated on the internal walls of the microreactor, versus various parameters are reported. It is shown that the radiation effects can impact the temperature of the solid phase of the porous medium and lead to alteration of Nusselt number. It is further observed that the transfer of mass is the main source of irreversibility in the system. The findings are of particular use for the design and analysis of the microreactors with homogenous chemical reactions and can be also used for the validation of computational models.

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More information

Published date: 1 April 2018

Identifiers

Local EPrints ID: 509054
URI: http://eprints.soton.ac.uk/id/eprint/509054
DOI: doi:10.1016/j.cep.2018.02.025
ISSN: 0255-2701
PURE UUID: fef483a3-9f5b-466a-a9b8-eb39bf8b7c68
ORCID for N. Karimi: ORCID iD orcid.org/0000-0002-4559-6245

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Date deposited: 10 Feb 2026 17:51
Last modified: 11 Feb 2026 03:18

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Contributors

Author: G. Hunt
Author: M. Torabi
Author: L. Govone
Author: N. Karimi ORCID iD
Author: A. Mehdizadeh

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