Analysis of the bifurcation structure near the excitation threshold of convection during uniform fluid infiltration through a slightly asymmetric porous chip
DOI:
https://doi.org/10.7242/1999-6691/2026.19.1.4Keywords:
porous medium, convective instability, bifurcation, symmetry, cosymmetryAbstract
Fluid-saturated porous scaffolds are crucial components of flow perfusion bioreactors, which act as microfluidic chips. These devices are used to grow cell cultures in a constant, steady-state environment through maintaining a continuous flow of nutrient-rich solution. Cell proliferation often occurs in non-isothermal conditions, which under gravity can lead to the onset of thermal convection. In this paper, we consider the problem of convection excitation in a porous chip heated from below, across which uniform pumping of an incompressible fluid is carried out. It has been known that incorporating a fluid-saturated porous structure into highly conductive impermeable medium leads to the fact that the boundary value problem takes on the cosymmetry property for any simply connected 2-D shape of the domain. This causes branching of one-parameter families of heterogeneous equilibrium states. Note however that even weak fluid pumping across the porous medium leads to cosymmetry breaking and the type of dynamic behavior of the system in this case depends on the domain symmetry. If under reflection the pumping domain is symmetric about the vertical axis, the resulting convection will be stationary. In the asymmetric domain, periodic oscillations are excited. In this paper, we investigate the bifurcation structure near the convection excitation threshold occurring in a weakly asymmetric domain. The main focus is on the transition from stationary to oscillatory convection. The study of the system includes the following issues: finding the basic state of the system analytically; linear analysis of its stability using the Galerkin method; analysis of weakly nonlinear solutions near the first bifurcation point using the method of multiple time scales. It has been shown that branching of solutions near the excitation threshold of convection in a weakly non-cosymmetric system of equations defined in a weakly asymmetric domain is of surprisingly complex nature. The transition process includes the Andronov--Hopf bifurcation, the birth and death of limiting cycles at the backward and forward tangential bifurcations of a pair of equilibria, respectively; and the formation of homoclinic trajectories. Stability maps are constructed on the planes of control parameters of the problem: the Rayleigh number for the porous medium, the thermal Péclet number, and the chip tilt angle, which acts as a symmetry imperfection parameter. Bifurcation diagrams of a dynamic system on its slow manifold are presented.
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References
Nield D.A., Bejan A. Convection in Porous Media. Springer International Publishing, 2017. 988 p. . DOI: 10.1007/978-3-319-49562-0
Siraev R.R. Fluid transport in Forchheimer porous medium with spatially varying porosity and permeability. Computational Continuum Mechanics. 2019. Vol. 12, no. 3. P. 281292. DOI: 10.7242/1999-6691/2019.12.3.24
Maryshev B.S., Lyubimova T.P., Lyubimov D.V. Stability of homogeneous seepage of a liquid mixture through a closed region of the saturated porous medium in the presence of the solute immobilization. International Journal of Heat and Mass Transfer. 2016. Vol. 102. P. 113121. DOI: 10.1016/j.ijheatmasstransfer.2016.06.016
Kolchanova E.A., Kolchanov N.V. Convective solute transport in a sloping two-layered active porous medium with a pore clogging eect. International Communications in Heat and Mass Transfer. 2025. Vol. 161. P. 108526. DOI: 10.1016/j.icheatmasstransfer.2024.108526
De Wit A. Chemo-Hydrodynamic Patterns and Instabilities. Annual Review of Fluid Mechanics. 2020. Vol. 52, no. 1. P. 531555. DOI: 10.1146/annurev-uid-010719-060349
Varma M.V., Kandasubramanian B., Ibrahim S.M. 3D printed scaolds for biomedical applications. Materials Chemistry and Physics. 2020. Vol. 255. P. 123642. DOI: 10.1016/j.matchemphys.2020.123642
Zhianmanesh M., Varmazyar M., Montazerian H. Fluid Permeability of Graded Porosity Scaolds Architectured with Minimal Surfaces. ACS Biomaterials Science &; Engineering. 2019. Vol. 5, no. 3. P. 12281237. DOI: 10.1021/acsbiomaterials.8b01400
Krasnyakov I., Bratsun D. Cell-Based Modeling of Tissue Developing in the Scaold Pores of Varying Cross-Sections. Biomimetics. 2023. Vol. 8. P. 562. DOI: 10.3390/biomimetics8080562
Bratsun D., Elenskaya N., Siraev R., Tashkinov M. Numerical Analysis of Permeability of Functionally Graded Scaolds. Fluid Dynamics & Materials Processing. 2024. Vol. 20, no. 7. P. 14631479. DOI: 10.32604/fdmp.2024.047928
Bratsun D., Kostarev K. Phase Transition in a Dense Swarm of Self-Propelled Bots. Fluid Dynamics & Materials Processing. 2024. Vol. 20, no. 8. P. 17851798. DOI: 10.32604/fdmp.2024.048206
Lapwood E.R. Convection of a uid in a porous medium. Mathematical Proceedings of the Cambridge Philosophical Society. 1948. Vol. 44, no. 4. P. 508521. DOI: 10.1017/S030500410002452X
Riley D.S., Winters K.H. Modal exchange mechanisms in Lapwood convection. Journal of Fluid Mechanics. 1989. Vol. 204. P. 325358. DOI: 10.1017/S0022112089001771
Gershuni G.Z., Zhuhovitsky E.M. Convective Stability of Incompressible Fluids. Jerusalem: Keter Publishing House, 1976. 330 p.
Lyubimov D.V. Convective motions in a porous medium heated from below. Journal of Applied Mechanics and Technical Physics. 1975. Vol. 16, no. 2. P. 257261. DOI: 10.1007/BF00858924
Glukhov A.F., Lyubimov D.V., Putin G.F. Konvektivnyye dvizheniya v poristoy srede vblizi poroga neustoychivosti ravnovesiya. Doklady Akademii nauk SSSR. 1978. Vol. 238, no. 3. P. 549551.
Yudovich V.I. Cosymmetry, degeneration of solutions of operator equations, and onset of a ltration convection. Mathematical Notes of the Academy of Sciences of the USSR. 1991. Vol. 49. P. 540545. DOI: 10.1007/BF01142654
Yudovich V.I. Secondary cycle of equilibria in a system with cosymmetry, its creation by bifurcation and impossibility of symmetric treatment of it. Chaos: An Interdisciplinary Journal of Nonlinear Science. 1995. Vol. 5, no. 2. P. 402411. DOI: 10.1063/1.166110
Govorukhin V.N., Yudovich V.I. Bifurcations and selection of equilibria in a simple cosymmetric model of ltrational convection. Chaos: An Interdisciplinary Journal of Nonlinear Science. 1999. Vol. 9, no. 2. P. 403412. DOI: 10.1063/1.166417
Yudovich V.I. Bifurcations under perturbations violating cosymmetry. Doklady Physics. 2004. Vol. 49. P. 522526. DOI: 10.1134/1.1810578
Tsybulin V.G., Karasözen B., Ergenç T. Selection of steady states in planar Darcy convection. Physics Letters A. 2006. Vol. 356, no. 3. P. 189194. DOI: 10.1016/j.physleta.2006.03.043
Karasözen B., Tromova A.V., Tsybulin V.G. Natural convection in porous annular domains: Mimetic scheme and family of steady states. Journal of Computational Physics. 2012. Vol. 231, no. 7. P. 29953005. DOI: 10.1016/j.jcp.2012.01.004
Kurakin L.G., Kurdoglyan A.V. Semi-Invariant Form of Equilibrium Stability Criteria for Systems with One Cosymmetry. Russian Journal of Nonlinear Dynamics. 2019. Vol. 15, no. 4. P. 525531. DOI: 10.20537/nd190411
Bratsun D.A., Lyubimov D.V., Roux B. Co-symmetry breakdown in problems of thermal convection in porous medium. Physica D: Nonlinear Phenomena. 1995. Vol. 82. P. 398417. DOI: 10.1016/0167-2789(95)00045-6
Nilsen T., Storesletten L. An Analytical Study on Natural Convection in Isotropic and Anisotropic Porous Channels. Journal of Heat Transfer. 1990. Vol. 112. P. 396401. DOI: 10.1115/1.2910390
Storesletten L., Tveitereid M. Natural convection in a horizontal porous cylinder. International Journal of Heat and Mass Transfer. 1991. Vol. 34. P. 19591968. DOI: 10.1016/0017-9310(91)90207-U
Nayfeh A.H. Introduction in perturbation techniques. New York: Wiley-VCH, 1981. 533 p.
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