MODELING OF A MICROPOLAR THIN FILM FLOW WITH RAPIDLY VARYING THICKNESS AND NON-STANDARD BOUNDARY CONDITIONS

doi:10.1007/s10473-026-0113-6

Abstract

Abstract: In this paper, we study the asymptotic behavior of the micropolar fluid flow through a thin domain, assuming zero Dirichlet boundary condition on the top boundary, which is rapidly oscillating, and non-standard boundary conditions on the flat bottom. Assuming ``Reynolds roughness regime", in which the thickness of the domain is very small compared to the wavelength of the roughness (i.e. a very slight roughness), we rigorously derive a generalized Reynolds equation for pressure, clearly showing the roughness-induced effects. Moreover, we give expressions for the average velocity and microrotation.

Key words: micropolar fluid, thin-film flow, rapidly oscillating boundary, nonzero boundary conditions, homogenization

CLC Number:

35B27

María ANGUIANO¹, Francisco Javier SUÁREZ-GRAU^2,*. MODELING OF A MICROPOLAR THIN FILM FLOW WITH RAPIDLY VARYING THICKNESS AND NON-STANDARD BOUNDARY CONDITIONS[J].Acta mathematica scientia,Series B, 2026, 46(1): 209-242.

Trendmd

References

[1] Allaire G. Homogenization of the Stokes flow in a connected porous medium. Asymptot Anal, 1989, $\bf{2}$(3): 203-222
[2] Anguiano M. On the non-stationary non-Newtonian flow through a thin porous medium. ZAMM Z Angew Math Mech, 2017, $\bf{97}$(8): 895-915
[3] Anguiano M, Suárez-Grau F J. Nonlinear Reynolds equations for non-Newtonian thin-film fluid flows over a rough boundary. IMA J Appl Math, 2019, $\bf{84}$(1): 63-95
[4] Anguiano M, Suárez-Grau F J. Mathematical derivation of a Reynolds equation for magneto-micropolar fluid flows through a thin domain. Z Angew Math Phys, 2024, $\bf{75}$: Article 28
[5] Bayada G, Benhaboucha N, Chambat M. New models in micropolar fluid and their application to lubrication. Math Models Methods Appl Sci, 2005, $\bf{15}$(3): 343-374
[6] Bayada G, Benhaboucha N, Chambat M. Wall slip induced by a micropolar fluid. J Eng Math, 2008, $\bf{60}$: 89-100
[7] Bayada G, Chambat M. New models in the theory of the hydrodynamic lubrication of rough surfaces. J Tribol, 1988, $\bf{110}$(3): 402-407
[8] Bayada G, Chambat M. Homogenization of the Stokes system in a thin film flow with rapidly varying thickness. RAIRO Modél Math Anal Numér, 1989, $\bf{23}$(2): 205-234
[9] Bayada G, Chambat M, Gamouana S R. About thin film micropolar asymptotic equations. Quart Appl Math, 2001, $\bf{59}$(3): 413-439
[10] Bayada G, Chambat M, Gamouana S R. Micropolar effects in the coupling of a thin film past a porous medium. Asymptot Anal, 2002, $\bf{30}$(3/4): 187-216
[11] Bayada G, Lukaszewicz G. On micropolar fluids in the theory of lubrication. Rigorous derivation of an analogue of the Reynolds equation. Internat J Engrg Sci, 1996, $\bf{34}$(13): 1477-1490
[12] Bene${\rm \check{s}}$ M, Pa${\rm \check{z}}$anin I, Radulović M, Rukavina B. Nonzero boundary conditions for the unsteady micropolar pipe flow: Well-posedness and asymptotics. Appl Math Comput, 2022, $\bf{427}$: Article 127184
[13] Benhaboucha N, Chambat M, Ciuperca I. Asymptotic behaviour of pressure and stresses in a thin film flow with a rough boundary. Quart Appl Math, 2005, $\bf{63}$(2): 369-400
[14] Bessonov N M. A new generalization of the Reynolds equation for a micropolar fluid and its application to bearing theory. Tribol Int, 1994, $\bf{27}$(2): 105-108
[15] Bessonov N M. Boundary viscosity conception in hydrodynamical theory of lubrication. Proceeding of the Academy of Science of the USSR, 1968, $\bf{179}$(1): 49-52
[16] Bonnivard M, Pažanin I, Suárez-Grau F J. Effects of rough boundary and nonzero boundary conditions on the lubrication process with micropolar fluid. Eur J Mech B/Fluids, 2018, $\bf{72}$: 501-518
[17] Bonnivard M, Pažanin I, Suárez-Grau F J. A generalized Reynolds equation for micropolar flows past a ribbed surface with nonzero boundary conditions. ESAIM: Math Model Numer Anal, 2022, $\bf{56}$(4): 1255-1305
[18] Boukrouche M.A Reynolds equation rigorously derived from the micropolar Navier-Stokes system//Salvi R. The Navier-Stokes Equations. Boca Raton: CRC press, 2001: 1-22
[19] Boukrouche M, Paoli L. Asymptotic analysis of a micropolar fluid flow in a thin domain with a free and rough boundary. SIAM J Math Anal, 2012, $\bf{44}$(2): 1211-1256
[20] Boukrouche M, Paoli L, Ziane F. Unsteady micropolar fluid flow in a thin domain with Tresca fluid-solid interface law. Comput Math Appl, 2019, $\bf{77}$(11): 2917-2932
[21] Boukrouche M, Paoli L, Ziane F. Micropolar fluid flow in a thick domain with multiscale oscillating roughness and friction boundary conditions. J Math Anal Appl, 2021, $\bf{495}$(1): 124688
[22] Boyer F, Fabrie P.Mathematical Tools for the Study of the Incompressible Navier-Stokes Equations and Related Models. New York: Springer, 2013
[23] Cioranescu D, Damlamian A, Griso G. Periodic unfolding and homogenization. C R Acad Sci Paris Ser I, 2002, $\bf{335}$(1): 99-104
[24] Cioranescu D, Damlamian A, Griso G. The periodic unfolding method in homogenization. SIAM J Math Anal, 2008, $\bf{40}$(4): 1585-1620
[25] Dupuy D, Panasenko G, Stavre R. Asymptotic methods for micropolar fluids in a tube structure. Math Models Methods Appl Sci, 2004, $\bf{14}$(5): 735-758
[26] Dupuy D, Panasenko G, Stavre R. Asymptotic solution for a micropolar flow in a curvilinear channel. ZAMM Z Angew Math Mech, 2008, $\bf{88}$(10): 793-807
[27] Eringen A C. Theory of micropolar fluids. J Math Mech, 1966, $\bf{16}$(1): 1-18
[28] Fabricius J, Tsandzana A, Perez-Rafols F, Wall P. A comparison of the roughness regimes in hydrodynamic lubrication. J Tribol, 2017, $\bf{139}$(5): Article 051702
[29] Jacobson B O.At the boundary between lubrication and wear//Hutchings I M, ed. First World Tribology Conference. London: Mech Eng Pub, 1997: 291-298
[30] Léger L, Hervet H, Pit R.Friction and flow with slip at fluid-solid interfaces, Interfacial properties on the submicron scale//Frommer J, Overney R M, Eds. Interfacial Properties on the Submicrometer Scale. Washington: American Chemical Society, 2000: 154-167
[31] Lukaszewicz G. Micropolar Fluids,Theory and Applications. Boston: Birkha$\ddot{\rm u}$ser, 1999
[32] Mahabaleshwar U S, Pažanin I, Radulović M, Suárez-Grau F J. Effects of small boundary perturbation on the MHD duct flow. Theor Appl Mech, 2017, $\bf{44}$(1): 83-101
[33] Marušić-Paloka E, Pažanin I, Marušić S. An effective model for the lubrication with micropolar fluid. Mech Res Commun, 2013, $\bf{52}$: 69-73
[34] Marušić-Paloka E, Pa${\rm \check{z}}$anin I, Radulović M. Flow of a micropolar fluid through a channel with small boundary perturbation. Z Naturforsch A, 2016, $\bf{71}$(7): 607-619
[35] Marušić-Paloka E, Pa${\rm \check{z}}$anin I, Radulović M. Justification of the higher order effective model describing the lubrication of a rotating shaft with micropolar fluid. Symmetry, 2020, $\bf{12}$(3): Article 334
[36] Mikelić A. Remark on the result on homogenization in hydrodynamical lubrication by G. Bayada and M. Chambat. RAIRO Modél Math Anal Numér, 1991, $\bf{25}$(3): 363-370
[37] Nakasato J C, Pažanin I. Homogenization of the non-isothermal, non-Newtonian fluid flow in a thin domain with oscillating boundary. Z Angew Math Phys, 2023, $\bf{74}$: Article 211
[38] Pažanin I. Asymptotic behavior of micropolar fluid flow through a curved pipe. Acta Appl Math, 2011, $\bf{116}$: Article 1
[39] Pažanin I. Asymptotic analysis of the lubrication problem with nonstandard boundary conditions for microrotation. Filomat, 2016, $\bf{30}$(8): 2233-2247
[40] Pažanin I, Radulović M. Asymptotic analysis of the nonsteady micropolar fluid flow through a curved pipe. Appl Anal, 2020, $\bf{99}$(12): 2045-2092
[41] Pažanin I, Suárez-Grau F J. Analysis of the thin film flow in a rough domain filled with micropolar fluid. Comput Math Appl, 2014, $\bf{68}$(12): 1915-1932
[42] Pažanin I, Suárez-Grau F J. Homogenization of the Darcy-Lapwood-Brinkman flow in a thin domain with highly oscillating boundaries. B Malays Math Sci So, 2019, $\bf{42}$: 3073-3109
[43] Pažanin I, Suárez-Grau F J. Roughness-induced effects on the thermomicropolar fluid flow through a thin domain. Stud Appl Math, 2023, $\bf{151}$(2): 716-751
[44] Suárez-Grau F J. Asymptotic behavior of a non-Newtonian flow in a thin domain with Navier law on a rough boundary. Nonlin Anal, 2015, $\bf{117}$: 99-123
[45] Suárez-Grau F J. Analysis of the roughness regime for micropolar fluids via homogenization. Bull Malays Math Sci Soc, 2021, $\bf{44}$: 1613-1652
[46] Suárez-Grau F J. Mathematical modeling of micropolar fluid flows through a thin porous medium. J Eng Math, 2021, $\bf{126}$: Article 7
[47] Suárez-Grau F J. Homogenization of a micropolar fluid past a porous media with nonzero spin boundary condition. Math Meth Appl Sci, 2021, $\bf{44}$(6): 4835-4857
[48] Tartar L.Incompressible fluid flow in a porous medium convergence of the homogenization process//Brézis H, Lions J L, Eds. Nonlinear Partial Differential Equations and Their Applications: Coll$\grave{\rm e}$ge de France Seminar, Vol. II. Berlin: Springer, 1980: 368-377