In this paper, a mathematical model of Hele-Shaw flow was developed on the basis of the field equation of micropolar fluid. The motion equation of micropolar fluid was extended to flow in porous media, contributing to the mathematical model of the unsteady radial flow of micropolar fluid in an infinite reservoir. The relations between flow velocity, pressure gradient and flow rate were obtained by solving the mathematical model under fixed production internal boundary and fixed-pressure external boundary conditions. In addition, the effect of the physical properties of micropolar fluid on its flow was analyzed. The results indicated a significant dependence between the apparent permeability and physical properties of micropolar fluid, which clearly deviated from the Newtonian fluid. The results showed that, as the ratio of rotational viscous force to Newtonian viscous force in the micropolar parameter and the characteristic length of the micropolar metamaterial increase, the non-Newtonian characteristics of the fluid become gradually more significant. The non- Newtonian behavior of micropolar fluid consequently becomes unneglected, leading to a decreasing apparent permeability. Compared with a Newtonian fluid, a micropolar fluid causes obvious flow resistance, resulting in larger energy consumption and lower flow rate. This study can provide an academic reference for nonlinear rheology and the flow of heterogeneous fluids in the fields of petroleum engineering and biofluid flow.

Cited as: Zhu, W. Theoretical study of micropolar fluid flow in porous media. Advances in Geo-Energy Research, 2021, 5(4): 465-472, doi: 10.46690/ager.2021.04.11

Aydin, O., Pop, I. Natural convection from a discrete heater in enclosures filled with a micropolar fluid. International Journal of Engineering Science, 2005, 43(19-20): 1409-1418.

Biao, F., Liu, H., Zhang, S., et al. A numerical study of parameter influences on horizontal hydraulic fracture. Engineering Mechanics, 2011, 28: 228-235. (in Chinese)

Chang-Jian, C. W., Chen, C. K. Nonlinear dynamic analysis of a flexible rotor supported by micropolar fluid film journal bearings. International Journal of Engineering Science, 2006, 44: 1050-1070.

Chen, Z. M., Price, W. G. Decay estimates of linearized micropolar fluid flows in R3 space with applications to L3-strong solutions. International Journal of Engineering Science, 2006, 44(13-14): 859-873.

Deng, Q., Hu, M., Kane, O. I., et al. Syn-rift sedimentary evolution and hydrocarbon reservoir models in a graben rift sag, Songliao Basin, northeast China. Marine and Petroleum Geology, 2021, 132: 105245.

Ellahi, R., Rahman, S., Gulzar, M. M., et al. A mathematical study of non-Newtonian micropolar fluid in arterial blood flow through composite stenosis. Applied Mathematics and Information Sciences, 2014, 8(4): 1567-1573.

Eringen, A. C. Theory of micropolar fluids. Journal of Mathematics and Mechanics, 1966, 16(1): 1-18.

Faltas, M. S., Saad, E. I. Stokes flow with slip caused by the axisymmetric motion of a sphere bisected by a free surface bounding a semi-infinite micropolar fluid. International Journal of Engineering Science, 2005, 43(11-12): 953-976.

Fatunmbi, E., Salawu, S. Thermodynamic second law analysis of magneto-micropolar fluid flow past nonlinear porous media with non-uniform heat source. Propulsion and Power Research, 2020, 9(3): 281-288.

Gao, F., Song, Y., Li, Z., et al. Lithofacies and reservoir characteristics of the lower cretaceous continental shahezi shale in the changling fault depression of Songliao Basin, NE China. Marine and Petroleum Geology, 2018, 98: 401-421.

Gao, Y., Gao, Y., Ibarra, D. E., et al. Clay mineralogical evidence for mid-latitude terrestrial climate change from the latest cretaceous through the earliest paleogene in the Songliao Basin, NE China. Cretaceous Research, 2021, 124: 104827.

Gu, C., Qiu, R., Liu, S., et al. Shear thickening effects of drag-reducing nanofluids for low permeability reservoir. Advances in Geo-Energy Research, 2020, 4(3): 317-325.

Huang, R., Wu, H. A modified multiple relaxation time lattice Boltzmann model for convection-diffusion equation. Journal of Computational Physics, 2014, 274: 50-63. (in Chinese)

Hussain, A., Malik, M., Awais, M., et al. Computational and physical aspects of mhd prandtl-eyring fluid flow analysis over a stretching sheet. Neural Computing and Applications, 2019, 31(1): 425-433.

Kondic, L., Palffy, M. P., Shelley, M. J. Models of non- Newtonian Hele-Shaw flow. Physical Review E, 1996, 54(5): 4536-4539.

Lhuillier, D., Rey, A. D. Nematic liquid crystals and ordered micropolar fluids. Journal of non-Newtonian Fluid Mechanics, 2004, 120(1-3): 169-174.

Lok, Y. Y., Pop, I., Chamkha, A. J. Non-orthogonal stagnation- point flow of a micropolar fluid. International Journal of Engineering Science, 2007, 45(1): 173-184.

Masuda, Y., Tang, K. C., Miyazawa, M., et al. 1D simulation of polymer flooding including the viscoelastic effect of polymer solution. SPE Reservoir Engineering, 1992, 7(2): 247-252.

Mohamadian, N., Ghorbani, H., Wood, D. A., et al. Rheological and filtration characteristics of drilling fluids enhanced by nanoparticles with selected additives: An experimental study. Advances in Geo-Energy Research, 2018, 2(3): 228-236.

Murthy, J., Srinivas, J. Second law analysis for poiseuille flow of immiscible micropolar fluids in a channel. International Journal of Heat and Mass Transfer, 2013, 65: 254-264.

Nabwey, H. A., Mahdy, A. Numerical approach of micropolar dust-particles natural convection fluid flow due to a permeable cone with nonlinear temperature. Alexandria Engineering Journal, 2021, 60(1): 1739-1749.

Prakash, J., Sinha, P. Lubrication theory for micropolar fluids and its application to a journal bearing. International Journal of Engineering Science, 1975, 13(3): 217-232. Pramod, K. Y., Sneha, J., Taimoor, A., et al. Influence of a magnetic field on the flow of a micropolar fluid sandwiched between two newtonian fluid layers through a porous medium. European Physical Journal Plus, 2018, 133(7): 247-260.

Pranesh, S. Effects of suction-injection-combination (SIC) on the onset of rayleigh-benard magnetoconvection in a micropolar fluid. International Journal of Engineering Science, 2003, 41(15): 1741-1766.

Qiu, Z. Hele-shaw flow for micropolar fluids. Journal of Fudan University (Natural Science), 1990, 29(2): 129-135. (in Chinese)

Roy, A. K., Beg, O. A. Mathematical modelling of unsteady solute dispersion in two-fluid (micropolar-newtonian) blood flow with bulk reaction. International Communications in Heat and Mass Transfer, 2021, 122: 105169.

Siddheshwar, P. G., Manjunath, S. Unsteady convective diffusion with heterogeneous chemical reaction in a plane-poiseuille flow of a micropolar fluid. International Journal of Engineering Science, 2000, 38(7): 765-783.

Su, J. Incompressible limit of a compressible micropolar fluid model with general initial data. Nonlinear Analysis, 2016, 132: 1-24.

Sun, S., Shu, L., Zeng, Y., et al. Porosity-permeability and textural heterogeneity of reservoir sandstones from the lower cretaceous putaohua member of yaojia formation, weixing oilfield, Songliao Basin, Northeast China. Marine and Petroleum Geology, 2007, 24(2): 109-127.

Wang, W., Liu, K., Jiao, M. Thermal and non-Newtonian analysis on mixed liquid-solid lubrication. Tribology International, 2007, 40(7): 1067-1074.

Wang, X. L., Liu, W. Derivation and application of energy equation for the lubrication with micropolar fluids. Journal of Beijing Institute of Technology, 2005, 25: 380-383. (in Chinese)

Wu, C., Liu, X., Liu, Y. Method of specific productivity index prediction of huanghekou sag and its application. Fault Block Oil and Gas Field, 2018, 25(2): 218-221. (in Chinese)

Yadav, P. K., Kumar, A. An inclined magnetic field effect on entropy production of non-miscible newtonian and micropolar fluid in a rectangular conduit. International Communications in Heat and Mass Transfer, 2021, 124: 105266.

Yang, X., Wang, H., Li, Z., et al. Tectonic-sedimentary evolution of a continental rift basin: A case study of the early cretaceous changling and lishu fault depressions, southern Songliao Basin, China. Marine and Petroleum Geology, 2021, 128: 105068.

Yi, S., Li, M., Xu, S., et al. Accumulation condition and model of buried hill in the central uplift, Songliao Basin, China. Journal of Natural Gas Geoscience, 2021, 6(3): 121-135.

Zhang, H., Xu, T., Zhang, X., et al. Study on local resistance of non-Newtonian power law fluid in elbow pipes. Journal of Thermal Science, 2016, 25(3): 287-291.

Zhang, L., Bao, Z., Dou, L., et al. Diagenetic alterations related to sedimentary architecture of deltaic distributary channels in red beds of the cretaceous yaojia formation, songliao basin. Journal of Petroleum Science and Engineering, 2021, 203: 108564.

Zhu, L., Yuan, Z., Xu, Y., et al. Shear thinning property analysis of non-Newtonian fluid mold flux. Steelmaking, 2017, 33(3): 25-30. (in Chinese)