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Rheologica Acta

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01-08-2009 | Original Contribution

What is behind the plastic strain rate?

Authors: Markus Hütter, Miroslav Grmela, Hans Christian Öttinger

Published in: Rheologica Acta | Issue 7/2009

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Abstract

The plastic strain rate plays a central role in macroscopic models on elasto-viscoplasticity. In order to discuss the concept behind this quantity, we propose, first, a kinetic toy model to describe the dynamics of sliding layers representative of plastic deformation of single crystalline metals. The dynamic variable is given by the distribution function of relative strains between adjacent layers, and the plastic strain rate emerges as the average hopping rate between energy wells. We demonstrate the behavior of this model under different deformations and how it captures the elastic-to-plastic transition. Second, the kinetic toy model is reduced to a closed evolution equation for the average of the relative strain, allowing us to make a direct link to macroscopic theories. It is shown that the constitutive relation for the plastic strain rate does not only depend on the stress, but also on the macroscopic applied deformation rate, contrary to common practice.

previous article Combined slit and plate–plate magnetorheometry of a magnetorheological fluid (MRF) and parameterization using the Casson model

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Andrade END, Henderson C (1951) The mechanical behaviour of single crystals of certain face-centered cubic metals. Philos Trans R Soc S-A 244(880):177–203CrossRefADS

Arsenlis A, Parks D, Becker R, Bulatov VV (2004) On the evolution of crystallographic dislocation density in non-homogeneously deforming crystals. J Mech Phys Solids 52:1213–1246MATHCrossRefADSMathSciNet

Asaro RJ (1983) Micromechanics of crystals and polycrystals. In: Hutchinson JW, Wu TY (eds) Advances in applied mechanics, vol 23. Academic, New York, pp 1–115CrossRef

Bauwens-Crowet C, Bauwens JC, Homès G (1969) Tensile yield-stress behavior of glassy polymers. J Polym Sci A-2 Polym Phys 7:735–742CrossRef

Beris AN, Edwards BJ (1994) Thermodynamics of flowing systems with internal microstructure. Oxford University, Oxford

Besseling JF, van der Giessen E (1993) Mathematical modelling of inelastic deformation (Applied mathematics and mathematical computation, vol 5). Chapmann and Hall, London

Bird BR, Curtiss CF, Armstrong RC, Hassager O (1987) Dynamics of polymeric liquids, vol 2: kinetic theory (2nd ed). Wiley, New York

Boyce MC, Parks DM, Argon AS (1988) Large inelastic deformation of glassy polymers. 1. rate dependent constitutive model. Mech Mater 7:15–33CrossRef

Callister Jr WD (2000) Materials science and engineering: an introduction. Wiley, New York

El-Azab A (2000) Statistical mechanics treatment of the evolution of dislocation distributions in single crystals. Phys Rev B 61:11956–11966CrossRefADS

Estrin Y (1996) Dislocation density-related constitutive modeling. In: Krausz AS, Krausz K (eds) Unified constitutive laws of plastic deformation. Academic, San Diego, pp 69–106CrossRef

Estrin Y, Braasch H, Brechet Y (1996) A dislocation density based constitutive model for cyclic deformation. J Eng Mater Technol ASME 118:441–447CrossRef

Gantchenko V, Jouinot P, Koster A (2008) Viscoplastic behaviour of metals deformed at high-temperature, application to tension-compression cycles. J Mater Sci 43:5342–5349CrossRefADS

Gardiner CW (1985) Handbook of stochastic methods for physics, chemistry and the natural sciences (2nd ed). Springer, Berlin

Gorban AN, Karlin IV (2005) Invariant manifolds for physical and chemical kinetics. Lecture notes in physics, vol 660. Springer, BerlinMATH

Grmela M, Öttinger HC (1997) Dynamics and thermodynamics of complex fluids. I. Development of a general formalism. Phys Rev E 56:6620–6632CrossRefADSMathSciNet

Groma I, Csikor FF, Zaiser M (2003) Spatial correlations and higher-order gradient terms in a continuum description of dislocation dynamics. Acta Mater 51:1271–1281CrossRef

Haasen P (1978) Physical metallurgy. Cambridge University Press, Cambridge

Hutchinson JW (1976) Bounds and self-consistent estimates for creep of polycrystalline materials. Proc R Soc Lond A Mat 348:101–127MATHCrossRefADS

Hütter M, Tervoort TA (2008a) Finite anisotropic elasticity and material frame indifference from a nonequilibrium thermodynamics perspective. J Non-Newton Fluid Mech 152:45–52MATHCrossRef

Hütter M, Tervoort TA (2008b) Thermodynamic considerations on non-isothermal finite anisotropic elasto-viscoplasticity. J Non-Newton Fluid Mech 152:53–65MATHCrossRef

Hütter M, Tervoort TA (2008c) Coarse graining in elasto-viscoplasticity: Bridging the gap from microscopic fluctuations to dissipation. In: van der Giessen E, Aref H (eds) Advances in applied mechanics, vol 42. Academic, New York, pp 253–317

Ilg P, Karlin IV, Öttinger HC (2002) Canonical distribution functions in polymer dynamics: (I). Dilute solutions of flexible polymers. Physica A 315:367–385MATHCrossRefADS

Ilg P, Karlin IV, Kröger M, Öttinger HC (2003) Canonical distribution functions in polymer dynamics: (II). Liquid-crystalline polymers. Physica A 319:134–150MATHCrossRefADS

Kocks UF (1976) Laws for work-hardening and low-temperature creep. J Eng Mater Technol ASME 98:76–85

Kocks UF, Mecking H (2003) Physics and phenomenology of strain hardening: the FCC case. Prog Mater Sci 48:171–273CrossRef

Kramers HA (1940) Brownian motion in a field of force and the diffusion model of chemical reactions. Physica (Utrecht) 7:284–304MATHCrossRefADSMathSciNet

Krausz A, Eyring H (1975) Deformation kinetics. Wiley-Interscience, London

Kröger M (2005) Models for polymeric and anisotropic liquids, Lect. Notes Phys. 675. Springer, BerlinMATH

Kubo R (1966) Fluctuation-dissipation theorem. Rep Prog Phys 29:255–284CrossRefADS

Kubo R, Toda M, Hashitsume N (1985) Statistical physics II: nonequilibrium statistical mechanics (2nd ed). Springer, New York

Kuhlmann-Wilsdorf D (1985) Theory of work-hardening 1934–1984. Metal Trans A 16:2091–2108CrossRef

Larson RG (1999) The structure and rheology of complex fluids. Oxford University Press, New York

Leonov AI (1976) Nonequilibrium thermodynamics and rheology of viscoelastic polymer media. Rheol Acta 15:85–98MATHCrossRef

Mecking H, Kocks UF (1981) Kinetics of flow and strain-hardening. Acta Metal 29:1865–1875CrossRef

Orowan E (1934) Plasticity of crystals. Z Phys 89:605–659CrossRefADS

Öttinger HC (1996) Stochastic processes in polymeric fluids: tools and examples for developing simulation algorithms (1st ed). Springer, BerlinMATH

Öttinger HC, Grmela M (1997) Dynamics and thermodynamics of complex fluids. II. Illustrations of a general formalism. Phys Rev E 56:6633–6655CrossRefADSMathSciNet

Öttinger HC (2005) Beyond equilibrium thermodynamics. Wiley, HobrokenCrossRef

Pan J, Rice JR (1983) Rate sensitivity of plastic-flow and implications for yield-surface vertices. Int J Solids Struct 19:973–987MATHCrossRef

Rubin MB (1994) Plasticity theory formulated in terms of physically based microstructural variables part 1. Theory. Int J Solids Struct 31:2615–2634MATHCrossRef

Rubin MB (1996) On the treatment of elastic deformation in finite elastic-viscoplastic theory. Int J Plast 12:951–965MATHCrossRef

Schmid E, Boas W (1935) Kristallplastizität. Springer, Berlin

Schulze V, Vöhringer O (2001) Plastic deformation: constitutive description. In: Buschow KHJ et al. (eds) Encyclopedia of materials: science and technology, vol 7. Elsevier, Amsterdam, pp 7050–7064

Tabourot L, Fivel M, Rauch E (1997) Generalised constitutive laws for fcc single crystals. Mat Sci Eng A Struct 234:639–642CrossRef

Taylor GI (1934) Plastic deformation of crystals. Proc R Soc Lond Sec A 145:362–404CrossRefADS

Tervoort TA, Smit RJM, Brekelmans WAM, Govaert LE (1998) A constitutive equation for the elasto-viscoplastic deformation of glassy polymers. Mech Time-Dep Mater 1:269–291CrossRefADS

Truesdell C, Noll W (1992) The non-linear field theories of mechanics (2nd ed). Springer, BerlinMATH

Von Polanyi M (1934) Lattice distortion which originates plastic flow. Z Phys 89, 660–662CrossRefADS

Ward IM (1983) Mechanical properties of solid polymers (2nd ed). Wiley, Chichester

Title: What is behind the plastic strain rate?
Authors: Markus Hütter
Miroslav Grmela
Hans Christian Öttinger
Publication date: 01-08-2009
Publisher: Springer-Verlag
Published in: Rheologica Acta / Issue 7/2009
Print ISSN: 0035-4511
Electronic ISSN: 1435-1528
DOI: https://doi.org/10.1007/s00397-009-0371-y

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