TY - JOUR
T1 - Dispersion coefficient in an electro-osmotic flow of a viscoelastic fluid through a microchannel with a slowly varying wall zeta potential
AU - Arcos, J. C.
AU - Méndez, F.
AU - Bautista, E. G.
AU - Bautista, O.
N1 - Publisher Copyright:
© 2018 Cambridge University Press.
PY - 2018/3/25
Y1 - 2018/3/25
N2 - The dispersion coefficient of a passive solute in a steady-state pure electro-osmotic flow (EOF) of a viscoelastic liquid, whose rheological behaviour follows the simplified Phan-Thien-Tanner (sPTT) model, along a parallel flat plate microchannel, is studied. The walls of the microchannel are assumed to have modulated and low potentials, which vary slowly in the axial direction in a sinusoidal manner. The flow field required to obtain the dispersion coefficient was solved using the lubrication approximation theory (LAT). The solution of the electric potential is based on the Debye-Hückel approximation for a symmetric electrolyte. The viscoelasticity of the fluid is observed to notably amplify the axial distribution of the effective dispersion coefficients due to the variation in the potentials of the walls. The problem was formulated for two cases: when the Debye layer thickness (EDL) was on the order of unity (thick EDL) and in the limit where the thickness of the EDL was very small compared with the height of the microchannel (thin EDL limit). Due to the coupling between the nonlinear governing equations and the sPTT fluid model, they were replaced by their approximate linearized forms and solved in the limit of using the regular perturbation technique. Here is the amplitude of the sinusoidal function of the potentials. Additionally, the numerical solution of the simplified governing equations was also obtained for and compared with the approximate solution, showing excellent agreement for . Note that the dispersion coefficient primarily depends on the Deborah number, on the ratio of the half-height of the microchannel to the Debye length, and on the assumed variation in the potentials of the walls.
AB - The dispersion coefficient of a passive solute in a steady-state pure electro-osmotic flow (EOF) of a viscoelastic liquid, whose rheological behaviour follows the simplified Phan-Thien-Tanner (sPTT) model, along a parallel flat plate microchannel, is studied. The walls of the microchannel are assumed to have modulated and low potentials, which vary slowly in the axial direction in a sinusoidal manner. The flow field required to obtain the dispersion coefficient was solved using the lubrication approximation theory (LAT). The solution of the electric potential is based on the Debye-Hückel approximation for a symmetric electrolyte. The viscoelasticity of the fluid is observed to notably amplify the axial distribution of the effective dispersion coefficients due to the variation in the potentials of the walls. The problem was formulated for two cases: when the Debye layer thickness (EDL) was on the order of unity (thick EDL) and in the limit where the thickness of the EDL was very small compared with the height of the microchannel (thin EDL limit). Due to the coupling between the nonlinear governing equations and the sPTT fluid model, they were replaced by their approximate linearized forms and solved in the limit of using the regular perturbation technique. Here is the amplitude of the sinusoidal function of the potentials. Additionally, the numerical solution of the simplified governing equations was also obtained for and compared with the approximate solution, showing excellent agreement for . Note that the dispersion coefficient primarily depends on the Deborah number, on the ratio of the half-height of the microchannel to the Debye length, and on the assumed variation in the potentials of the walls.
KW - low-Reynolds-number flows
KW - lubrication theory
KW - micro-/nano-fluid dynamics
UR - http://www.scopus.com/inward/record.url?scp=85041227375&partnerID=8YFLogxK
U2 - 10.1017/jfm.2018.11
DO - 10.1017/jfm.2018.11
M3 - Artículo
SN - 0022-1120
VL - 839
SP - 348
EP - 386
JO - Journal of Fluid Mechanics
JF - Journal of Fluid Mechanics
ER -