Effects of nanofluid and radiative heat transfer on the double-diffusive forced convection in microreactors
Effects of nanofluid and radiative heat transfer on the double-diffusive forced convection in microreactors
Understanding transport phenomena in microreactors remains challenging owing to the peculiar transfer features of microstructure devices and their interactions with chemistry. This paper, therefore, theoretically investigates heat and mass transfer in microreactors consisting of porous microchannels with thick walls, typical of real microreactors. To analyse the porous section of the microchannel, the local thermal non-equilibrium model of thermal transport in porous media is employed. A first-order, catalytic chemical reaction is implemented on the internal walls of the microchannel to establish the mass transfer boundary conditions. The effects of thermal radiation and nanofluid flow within the microreactor are then included within the governing equations. Further, the species concentration fields are coupled with that of the nanofluid temperature through considering the Soret effect. A semi-analytical methodology is used to tackle the resultant mathematical model with two different thermal boundary conditions. Temperature and species concentration fields as well as Nusselt number for the hot wall are reported versus various parameters such as porosity, radiation parameter and volumetric concentration of nanoparticles. The results show that radiative heat transfer imparts noticeable effects upon the temperature fields and consequently Nusselt number of the system. Importantly, it is observed that the radiation effects can lead to the development of a bifurcation in the nanofluid and porous solid phases and significantly influence the concentration field. This highlights the importance of including thermal radiation in thermochemical simulations of microreactors.
45–59
Govone, L.
a88be961-98b0-4616-8951-fae92aa69363
Torabi, M.
cca46013-f51a-4d5d-b8d0-7d54bcff33d0
Wang, L.
6776fc93-419c-493c-9964-d2ec21e4b598
Karimi, N.
620646d6-27c9-4e1e-948f-f23e4a1e773a
25 January 2018
Govone, L.
a88be961-98b0-4616-8951-fae92aa69363
Torabi, M.
cca46013-f51a-4d5d-b8d0-7d54bcff33d0
Wang, L.
6776fc93-419c-493c-9964-d2ec21e4b598
Karimi, N.
620646d6-27c9-4e1e-948f-f23e4a1e773a
Govone, L., Torabi, M., Wang, L. and Karimi, N.
(2018)
Effects of nanofluid and radiative heat transfer on the double-diffusive forced convection in microreactors.
Journal of Thermal Analysis and Calorimetry, 135, .
(doi:10.1007/s10973-018-7027-z).
Abstract
Understanding transport phenomena in microreactors remains challenging owing to the peculiar transfer features of microstructure devices and their interactions with chemistry. This paper, therefore, theoretically investigates heat and mass transfer in microreactors consisting of porous microchannels with thick walls, typical of real microreactors. To analyse the porous section of the microchannel, the local thermal non-equilibrium model of thermal transport in porous media is employed. A first-order, catalytic chemical reaction is implemented on the internal walls of the microchannel to establish the mass transfer boundary conditions. The effects of thermal radiation and nanofluid flow within the microreactor are then included within the governing equations. Further, the species concentration fields are coupled with that of the nanofluid temperature through considering the Soret effect. A semi-analytical methodology is used to tackle the resultant mathematical model with two different thermal boundary conditions. Temperature and species concentration fields as well as Nusselt number for the hot wall are reported versus various parameters such as porosity, radiation parameter and volumetric concentration of nanoparticles. The results show that radiative heat transfer imparts noticeable effects upon the temperature fields and consequently Nusselt number of the system. Importantly, it is observed that the radiation effects can lead to the development of a bifurcation in the nanofluid and porous solid phases and significantly influence the concentration field. This highlights the importance of including thermal radiation in thermochemical simulations of microreactors.
This record has no associated files available for download.
More information
Published date: 25 January 2018
Identifiers
Local EPrints ID: 509055
URI: http://eprints.soton.ac.uk/id/eprint/509055
ISSN: 1388-6150
PURE UUID: 8f494925-7839-4772-a12e-9f1b7555f38e
Catalogue record
Date deposited: 10 Feb 2026 17:51
Last modified: 11 Feb 2026 03:18
Export record
Altmetrics
Contributors
Author:
L. Govone
Author:
M. Torabi
Author:
L. Wang
Author:
N. Karimi
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics