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A Brief Review of Elasticity and Viscoelasticity for Solids

Published online by Cambridge University Press:  03 June 2015

Harvey Thomas Banks*
Affiliation:
Center for Research in Scientific Computation and Department of Mathematics, North Carolina State University, Raleigh, NC 27695-8212, USA
Shuhua Hu*
Affiliation:
Center for Research in Scientific Computation and Department of Mathematics, North Carolina State University, Raleigh, NC 27695-8212, USA
Zackary R. Kenz*
Affiliation:
Center for Research in Scientific Computation and Department of Mathematics, North Carolina State University, Raleigh, NC 27695-8212, USA
*
Corresponding author. URL: http://www.ncsu.edu/crsc/htbanks/ Email: htbanks@ncsu.edu

Abstract

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There are a number of interesting applications where modeling elastic and/or viscoelastic materials is fundamental, including uses in civil engineering, the food industry, land mine detection and ultrasonic imaging. Here we provide an overview of the subject for both elastic and viscoelastic materials in order to understand the behavior of these materials. We begin with a brief introduction of some basic terminology and relationships in continuum mechanics, and a review of equations of motion in a continuum in both Lagrangian and Eulerian forms. To complete the set of equations, we then proceed to present and discuss a number of specific forms for the constitutive relationships between stress and strain proposed in the literature for both elastic and viscoelastic materials. In addition, we discuss some applications for these constitutive equations. Finally, we give a computational example describing the motion of soil experiencing dynamic loading by incorporating a specific form of constitutive equation into the equation of motion.

Type
Research Article
Copyright
Copyright © Global-Science Press 2011

References

[1] Banks, H. T., Barnes, J. H., Eberhardt, A., Tran, H. and Wynne, S., Modeling and computation of propagating waves from coronary stenoses, Comput. Appl. Math., 21 (2002), pp. 767788.Google Scholar
[2] Banks, H. T., Hood, J. B., Medhin, N. G. and Samuels, J. R., A stick-slip/Rouse hybrid model for viscoelasticity in polymers, Technical Report CRSC-TR06-26, NCSU, November, 2006, Nonlinear. Anal. Real., 9 (2008), pp. 21282149.Google Scholar
[3] Banks, H. T. and Luke, N., Modelling of propagating shear waves in biotissue employing an internal variable approach to dissipation, Commun. Comput. Phys., 3 (2008), pp. 603640.Google Scholar
[4] Banks, H. T., Medhin, N. G. and Pinter, G. A., Nonlinear reptation in molecular based hysteresis models for polymers, Quart. Appl. Math., 62 (2004), pp. 767779.Google Scholar
[5] Banks, H. T., Medhin, N. G. and Pinter, G. A., Multiscale considerations in modeling of nonlinear elastomers, Technical Report CRSC-TR03-42, NCSU, October, 2003, J. Comp. Meth. Engr. Sci. Mech., 8 (2007), pp. 5362.Google Scholar
[6] Banks, H. T., Medhin, N. G. and Pinter, G. A., Modeling of viscoelastic shear: a nonlinear stick-slip formulation, CRSC-TR06-07, February, 2006, Dyn. Sys. Appl., 17 (2008), pp. 383406.Google Scholar
[7] Banks, H. T. and Pinter, G. A., Damping: hysteretic damping and models, CRSC-TR99-36, NCSU, December, 1999; Encyclopedia of Vibration (Braun, S. G., Ewins, D. and Rao, S., eds.), Academic Press, London, 2001, pp. 658664.Google Scholar
[8] Banks, H. T. and Pinter, G. A., A probabilistic multiscale approach to hysteresis in shear wave propagation in biotissue, Mult. Model. Sim., 3 (2005), pp. 395412.Google Scholar
[9] Banks, H. T., Pinter, G. A., Potter, L. K., Gaitens, M. J. and Yanyo, L. C., Modeling of quasistatic and dynamic load responses of filled viscoelastic materials, CRSC-TR98-48, NCSU, December, 1998; Chapter 11 in Mathematical Modeling: Case Studies from Industry (Cumberbatch, E. and Fitt, A., eds.), Cambridge University Press, 2001, pp. 229252.Google Scholar
[10] Banks, H. T., Pinter, G. A., Potter, L. K., Munoz, B. C. and Yanyo, L. C., Estimation and control related issues in smart material structures and fluids, CRSC-TR98-02, NCSU, January, 1998, Optimization Techniques and Applications (L. Caccetta, et al., eds.), Curtain Univ. Press, July, 1998, pp. 1934.Google Scholar
[11] Banks, H. T. and Samuels, J. R. Jr., Detection of cardiac occlusions using viscoelastic wave propagation, CRSC-TR08-23, North Carolina State University, 2008; AAMM., 1 (2009), pp. 128.Google Scholar
[12] Banks, H. T., A brief review of some approaches to hysteresis in viscoelastic polymers, CRSC-TR08-02, January, 2008; Nonlinear. Anal. Theor., 69 (2008), pp. 807815.Google Scholar
[13] Bardet, J. P., A viscoelastic model for the dynamic behavior of saturated poroelastic soils, J. Appl. Mech. ASME., 59 (1992), pp. 128135.Google Scholar
[14] Bird, R. B., Curtiss, C. F., Armstrong, R. C. and Hassager, O., Dynamics of Polymeric Liquids, Vol. 2, Kinetic Theory, Wiley, New York, 1987.Google Scholar
[15] Biot, M. A., Theory of propagation of elastic waves in a fluid saturated porous solid, J. Acust. Soc. Am., 28 (1956), pp. 168191.Google Scholar
[16] Christensen, R. M., Theory of Viscoelasticity, 2nd ed., Academic Proess, New York, 1982.Google Scholar
[17] Chouw, N. and Schmid, G., Wave Propagation, Moving Load, Vibration Reduction: Proceedings of the International Workshop WAVE 2002, Okayama, Japan, 18-20 September 2002, Taylor & Francis, 2003.Google Scholar
[18] Del Nobile, M. A., Chillo, S., Mentana, A. and Baiano, A., Use of the generalized Maxwell model for describing the stress relaxation behavior of solid-like foods, J. Food. Eng., 78 (2007), pp. 978983.Google Scholar
[19] Doi, M. and Edwards, M., The Theory of Polymer Dynamics, Oxford, New York, 1986.Google Scholar
[20] Drapaca, C. S., Sivaloganathan, S. and Tenti, G., Nonlinear constitutive laws in vis-coelasticity, Math. Mech. Solids., 12 (2007), pp. 475501.Google Scholar
[21] Ferry, J. D., Fitzgerald, E. R., Grandine, L. D. and Williams, M. L., Temperature dependence of dynamic properties of elastomers: relaxation distributions, Ind. Engr. Chem., 44 (1952), pp. 703706.Google Scholar
[22] Findley, W. N. and Lai, J. S. Y., A modified superposition principle applied to creep of nonlinear viscoelastic materials under abrupt changes in state of combined stress, Trans. Soc. Rheol., 11 (1967), pp. 361380.Google Scholar
[23] Findley, W. N., Lai, J. S. and Onaran, K., Creep and Relaxation of Nonlinear Vis-coelastic Materials, Dover Publications, New York, 1989.Google Scholar
[24] Fung, Y. C., Foundations of Solid Mechanics, Prentice-Hall, Englewood Cliffs, NJ, 1965.Google Scholar
[25] Fung, Y. C., Biomechanics: Mechanical Properties of Living Tissue, Springer-Verlag, Berlin, 1993.Google Scholar
[26] Fung, Y. C., A First Course in Continuum Mechanics, Prentice Hall, New Jersey, 1994.Google Scholar
[27] Green, A. E. and Rivlin, R. S., The mechanics of non-linear materials with memory, Arch. Ration. Mech. An., 1 (1957), pp. 121.Google Scholar
[28] Gurtin, M. and Sternberg, E., On the linear theory of viscoelasticity, Arch. Ration. Mech. An., 11 (1965), pp. 291365.Google Scholar
[29] Ter Haar, D., A phenomenological theory of viscoelastic behavior, Phys., 16 (1950), pp. 839– 850.Google Scholar
[30] Haddad, Y. M., Viscoelasticity of Engineering Materials, Chapman & Hall, Dordrecht, Netherlands, 1995.Google Scholar
[31] Hardin, B. O., The nature of damping in sands, J. Soil Mech. Found. Div., 91 (1965), pp. 6397.Google Scholar
[32] Johnson, A. R. and Stacer, R. G., Rubber viscoelasticity using the physically constrained systems stretches as internal variables, Rubber. Chem. Technol., 66 (1993), pp. 567577.Google Scholar
[33] Lakes, R. S., Viscoelastic Solids, CRC Press, Boca Raton, FL, 1998.Google Scholar
[34] Leaderman, H., Elastic and Creep Properties of Filamentous Materials, Textile Foundation, Washington, D.C., 1943.Google Scholar
[35] Le Tallec, P., Numerical Analysis of Viscoelastic Problems, Masson/Springer-Verlag, Paris/Berlin, 1990.Google Scholar
[36] Le Tallec, P., Rahier, C. and Kaiss, A., Three-dimensional incompressible viscoelasticity in large strains: formulation and numerical approximation, Comput. Meth. Appl. Mech. Eng., 109 (1993), pp. 233258.Google Scholar
[37] Lockett, F. J., Nonlinear Viscoelastic Solids, Academic, New York, 1972.Google Scholar
[38] Luke, N., Modeling Shear Wave Propagation in Biotissue: An Internal Variable Approach to Dissipation, Ph.D. thesis, North Carolina State University, Raleigh, NC, http://www.ncsu.edu/grad/etd/online.html, 2006.Google Scholar
[39] Marsden, J. E. and Hughes, T. J. R., Mathematical Foundations of Elasticity, Prentice-Hall, Englewood Cliffs, NJ, 1983.Google Scholar
[40] Michaels, P., Relating damping to soil permeability, Int. J. Geomech., 6 (2006), pp. 158165.Google Scholar
[41] Michaels, P., Water, inertial damping, and complex shear modulus, Geotech. SP., 2008.Google Scholar
[42] Morman, K. N. Jr. Rubber viscoelasticity-a review of current understanding, Proceedings of the Second Symposium on Analysis and Design of Rubber Parts, Jan. 1415, 1985.Google Scholar
[43] Oakley, J. G., Giacomin, A. J. and Yosick, J. A., Molecular origins of nonlinear viscoelas-ticity: fundamental review, Mikrochimica. Acta., 130 (1998), pp. 128.Google Scholar
[44] Ogden, R. W., Non-Linear Elastic Deformations, Dover Publications, 1984.Google Scholar
[45] Penneru, A. P., Jayaraman, K. and Bhattacharyya, D., Viscoelastic behaviour of solid wood under compressive loading, Holzforschung., 60 (2006), pp. 294298.Google Scholar
[46] Pipkin, A. C. and Rogers, T. G., A non-linear integral representation for viscoelastic behaviour, J. Mech. Phys. Solids., 16 (1968), pp. 5972.Google Scholar
[47] Richart, F. E. and Woods, J. R., Vibrations of Soils and Foundations, Prentice Hall, NJ, 1970.Google Scholar
[48] Rivlin, R. S., Large elastic deformations of isotropic materials, I, II, III, Phil. Trans. Roy. Soc. A., 240 (1948), pp. 459525.Google Scholar
[49] Rouse, P. E. Jr., A theory of the linear viscoelastic properties of dilute solutions of coiling polymers, J. Chem. Phys., 21 (1953), pp. 12721280.Google Scholar
[50] Samuels, J. R., Inverse Problems and Post Analysis Techniques for a Stenosis-Driven Acoustic Wave Propagation Model, Ph.D. thesis, North Carolina State University, Raleigh, NC, http://www.ncsu.edu/grad/etd/online.html, 2008.Google Scholar
[51] Schapery, R. A., On the characterization of nonlinear viscoelastic solids, Polymer. Eng. Sci., 9 (1969), pp. 295310.Google Scholar
[52] Schapery, R. A., Nonlinear viscoelastic and viscoplastic constitutive equations based on ther-modynamics, Mech. Time-Depend. Mat., 1 (1997), pp. 209240.Google Scholar
[53] Schapery, R. A., Nonlinear viscoelastic solids, Int. J. Solids. Struct., 37 (2000), pp. 359366.Google Scholar
[54] Schroder, C. T., Scott, W. R. Jr., AND Larson, G. D., Elastic waves interacting with buried land mines: a study using the FDTD method, IEEE Trans. Geosci. Remote. Sens., 40 (2002), pp. 14051415.Google Scholar
[55] Schwarzl, F. and Staverman, A. J., Higher approximation methods for the relaxation spectrum from static and dynamic measurements of viscoelastic materials, Appl. Sci. Res., A4 (1953), pp. 127141.Google Scholar
[56] Scott, W. R., Larson, G. D. and Martin, J. S., Simultaneous use of elastic and electromagnetic waves for the detection of buried land mines, Proc. SPIE., 4038 (2000), pp. 112.Google Scholar
[57] Shellhammer, T. H., Rumsey, T. R. and Krochta, J. M., Viscoelastic properties of edible lipids, J. Food. Eng., 33 (1997), pp. 305320.Google Scholar
[58] Smart, J. and Williams, J. G., A comparison of single integral non-linear viscoelasticity theories, J. Mech. Phys. Solids., 20 (1972), pp. 313324.Google Scholar
[59] Treloar, L. R. G., The Physics of Rubber Elasticity, 3rd edition, Oxford University Press, 1975.Google Scholar
[60] Truesdell, C., Rational Thermodynamics, Springer, Berlin, 1984.Google Scholar
[61] Wineman, A., Nonlinear viscoelastic solids-a review, Math. Mech. Solids., 14 (2009), pp. 300366.Google Scholar