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Abstract

A magnetoactive porous solid comprises a porous polymer matrix with embedded magnetizable particles. The connected porous space of the polymer matrix is filled with a fluid. Under externally applied magnetic fields, the magnetoactive porous solid can undergo large deformations in the elastic regime, triggering diffusive flow in the interconnected pores. The coupled hydromagnetomechanical behavior of such materials has recently received considerable attention. In this paper, the effective stress principle is applied to the constitutive modeling of the material at finite strains. In contrast to previous works, the Lagrangian porosity is no longer treated as an independent constitutive variable in the proposed formulation. To investigate the effect of the magnetic field on the mechanical response of the material, as well as to illustrate the theory, the problem of inflation of a circular cylindrical tube in the presence of a uniform axial magnetic field is formulated and solved. Computational results are presented graphically.

Keywords

Nonlinear magnetoporoelasticity nonlinear magnetoporoelastic coupling magnetoactive porous solids finite deformation effective stress

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References

Zhao

Kim

Cezar

, et al. Active scaffolds for on-demand drug and cell delivery. Proc Natl Acad Sci USA 2011; 108(1): 67–72.

Hong

Jung

Yen

, et al. Magnetoactive sponges for dynamic control of microfluidic flow patterns in microphysiological systems. Lab Chip 2014; 14: 514–521.

Cezar

Kennedy

Mehta

, et al. Biphasic ferrogels for triggered drug and cell delivery. Adv Healthcare Mater 2014; 3(11): 1869–1876.

Brown

WF.

Magnetoelastic interactions. New York: Springer, 1966.

Pao

. Electromagnetic forces in deformable continua. In: Nemat-Nasser

(ed.) Mechanics today, vol. 4. New York: Pergamon Press, 1978, 209–306.

Maugin

GA.

Continuum mechanics of electromagnetic solids. Amsterdam: North-Holland, 1988.

Eringen

Maugin

GA.

Electrodynamics of continuum I. New York: Springer, 1990.

Dorfmann

Ogden

RW.

Nonlinear magnetoelastic deformations. Q J Mech Appl Math 2004; 57(4): 599–622.

Dorfmann

Ogden

RW.

Some problems in nonlinear magnetoelasticity. Z Angew Math Phys 2005; 56: 718–745.

10.

Steigmann

DJ.

Equilibrium theory for magnetic elastomers and magnetoelastic membranes. Int J Nonlinear Mech 2004; 39: 1193–1216.

11.

Kankanala

Triantafyllidis

On finitely strained magnetorheological elastomers. J Mech Phys Solids 2004; 52: 2869–2908.

12.

Bustamante

Dorfmann

Ogden

RW.

On variational formulations in nonlinear magnetoelastostatics. Math Mech Solids 2008; 13: 725–745.

13.

Otténio

Destrade

Ogden

RW.

Incremental magnetoelastic deformations, with application to surface instability. J Elast 2008; 90: 19–42.

14.

Kankanala

Triantafyllidis

Magnetoelastic buckling of a rectangular block in plane strain. J Mech Phys Solids 2008; 56: 1147–1169.

15.

Reddy

Saxena

Instabilities in the axisymmetric magnetoelastic deformation of a cylindrical membrane. Int J Solids Struct 2018; 136–137: 203–219.

16.

Bustamante

Transversely isotropic nonlinear magneto-active elastomers. Acta Mech 2010; 210: 183–214.

17.

Danas

Kankanala

Triantafyllidis

Experiments and modeling of iron-particle-filled magnetorheological elastomers. J Mech Phys Solids 2012; 60: 120–138.

18.

Saxena

Hossain

Steinmann

A theory of finite deformation magneto-viscoelasticity. Int J Solids Struct 2013; 50: 3886–3897.

19.

Nedjar

A modelling framework for finite strain magnetoviscoelasticity. Math Mech Solids 2020; 25(2): 288–304.

20.

Garcia-Gonzalez

Hossain

A microstructural-based approach to model magneto-viscoelastic materials at finite strains. Int J Solids Struct 2021; 208–209: 119–132.

21.

Ethiraj

Miehe

Multiplicative magneto-elasticity of magnetosensitive polymers incorporating micromechanically-based network kernels. Int J Eng Sci 2016; 102: 93–119.

22.

Bustamante

Dorfmann

Ogden

RW.

Numerical solution of finite geometry boundary-value problems in nonlinear magnetoelasticity. Int J Solids Struct 2011; 48: 874–883.

23.

Haldar

Kiefer

Menzel

Finite element simulation of rate-dependent magneto-active polymer response. Smart Mater Struct 2016; 25: 104003.

24.

Keip

Rambausek

A multiscale approach to the computational characterization of magnetorheological elastomers. Int J Numer Methods Eng 2016; 107(4): 338–360.

25.

Nedjar

A coupled BEM–FEM method for finite strain magneto-elastic boundary-value problems. Comput Mech 2017; 59: 795–807.

26.

Lum

Mastrangeli

, et al. Small-scale soft-bodied robot with multimodal locomotion. Nature 2018; 554: 81–85.

27.

Ren

Dong

, et al. Multi-functional soft-bodied jellyfish-like swimming. Nat Commun 2019; 10: 2703.

28.

Bostola

Hossain

A review on magneto-mechanical characterizations of magnetorheological elastomers. Compos Part B Eng 2020; 200: 108348.

29.

Morillas

de Vicente

Magnetorheology: A review. Soft Matter 2020; 16: 9614–9642.

30.

Nedjar

A theory of finite strain magneto-poromechanics. J Mech Phys Solids 2015; 84: 293–312.

31.

Gebhart

Wallmersperger

A general framework for the modeling of porous ferrogels at finite strains. J Mech Phys Solids 2019; 122: 69–83.

32.

Coussy

Poromechanics. Chichester: John Wiley & Sons, 2004.

33.

Nedjar

Formulation of a nonlinear porosity law for fully saturated porous media at finite strains. J Mech Phys Solids 2013; 61(2): 537–556.

34.

Ogden

. Magnetostatics: From basic principles to nonlinear interactions in deformable media. In: Ogden

Steigmann

(eds.) Mechanics and elastodynamics of magneto- and electro-elastic materials (CISM Courses and Lectures, vol. 527). Vienna: Springer, 2011, 107–152.

35.

Dorfmann

Ogden

RW.

Nonlinear theory of electroelastic and magnetoelastic interactions. New York: Springer, 2014.

36.

Spencer

AJM

. Theory of invariants. In: Eringen

(ed.) Continuum physics, vol. 1. New York: Academic Press, 1971, 239–353.

37.

Holzapfel

GA.

Nonlinear solid mechanics: A continuum approach for engineering. Chichester: John Wiley & Sons, 2000.

38.

Coussy

Mechanics and physics of porous solids. Chichester: John Wiley & Sons, 2010.

39.

Zheng

Zhang

On the effective stress law and its application to finite deformation problems in a poroelastic solid. Int J Mech Sci 2019; 161–162: 105074.

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Nonlinear magnetoelastic deformations of porous solids

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