In the present research, by using finite volume method and applying a first-order slip boundary condition, the effect of
porous media on the mixing process of CO and N2 gases in the T-shaped micromixer is investigated. The effect of the
permeability coefficient of the porous medium (Darcy number) and its length on the quality of mixing and heat transfer
have been investigated. The results indicate that the increase of the length of porous medium leads to an increase of the
length of entrance region by blocking the flow and causes the improvement of the mixing process and reduction of the
mixing lengths. The obtained results show that, by decreasing Darcy number, the quality of mixing has been improved
and the mixing length is reduced. According to the results, when there is no porous media, the complete mixing is
accrued at x=L = 0.54, and the presence of the porous media (Da number = 0.001, length of porous media = 2 m)
leads to complete mixing at x=L = 0.2. The results demonstrate that the use of a porous medium reduces the thermal
entrance length and increases the temperature difference between gases and micromixer walls that causes the reduction
of heat transfer coefficient and Nusselt number. The results show that when there is no porous media the Nusselt
number is 4, whereas with the existence of the porous media (Da number = 0.001, length of porous media = 2 m)
the Nusselt number is 1.9. The influence of Knudsen number on the mixing efficiency is investigated, too. According
to the results, by increasing Knudsen number, the heat transfer and friction coefficient decrease; however, due to the
improvement of permeability of species, because of Knudsen number increment, the mixing has been improved and the
length of mixing reduces.