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IssuesArchive of Issues2018-6pp.623-632

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E.L. Aero, A.N. Bulygin, and Yu.V. Pavlov, "Nonlinear Deformation Model of Crystal Media Allowing Martensite Transformations: Solution of Static Equations," Mech. Solids. 53 (6), 623-632 (2018)
Year 2018 Volume 53 Number 6 Pages 623-632
DOI 10.3103/S0025654418060043
Title Nonlinear Deformation Model of Crystal Media Allowing Martensite Transformations: Solution of Static Equations
Author(s) E.L. Aero (Institute of Problems in Mechanical Engineering of the Russian Academy of Sciences, Bol'shoy pr. 61, St. Petersburg, 199078 Russia)
A.N. Bulygin (Institute of Problems in Mechanical Engineering of the Russian Academy of Sciences, Bol'shoy pr. 61, St. Petersburg, 199078 Russia, bulygin_an@mail.ru)
Yu.V. Pavlov (Institute of Problems in Mechanical Engineering of the Russian Academy of Sciences, Bol'shoy pr. 61, St. Petersburg, 199078 Russia)
Abstract Mathematical methods are developed for solving the statics equations of a non-linear model of deforming a crystalline medium with a complex lattice that allows martensitic transformations. In the nonlinear theory, the deformation describes the vector of the acoustic mode U(t,x,y,z) and the vector of the optical mode u(t,x,y,z). They are found from a system of six related nonlinear equations. The vector of the acoustic mode U(t,x,y,z) is sought in the Papkovich-Neuber form. A system of six related nonlinear equations is transformed into a system of individual equations. The equations of the optical mode u(t,x,y,z) are reduced to one sine-Gordon equation with a variable coefficient (amplitude) in front of the sine and two Poisson equations. The definition of the acoustic mode is reduced to solving the scalar and vector Poisson equations. For a constant-amplitude optical mode, particular solutions were found. In the case of plane deformation, a class of doubly-periodic solutions is constructed, which are expressed in terms of Jacobi elliptic functions. The analysis of the solutions found is conducted. It is shown that the nonlinear theory describes the fragmentation of the crystalline medium, the formation of boundaries between fragments, phase transformations, the formation of defects and other deformation features that are realized in the field of high external force effects and which are not described by classical continuum mechanics.
Keywords complex lattice, nonlinear model, sine-Gordon equation, defects, fragmentation, phase transformations
References
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2.  E.L. Aero, "Substantially Nonlinear Micromechanics of a Medium with a Variable Periodic Structure," Usp. Mekh., No. 1, 130-176 (2002)
3.  M.Born and K.Huang, Dynamical Theory of Crystal Lattices (Clarendon Press, Oxford, 1954; Izd-vo Inostrannoi Literatury, Moscow, 1958).
4.  D.A. Indeytsev, Yu.I. Meshcheryakov, A.Yu. Kuchmin, and D.S. Vavilov, "A Multiscale Model of Propagation of Steady Elasto-Plastic Waves," Dokl. Ross. Akad. Nauk 458 (2), 490-493 (2014) [Dokl. Phys. (Engl. Transl.) 59 (9), 423-426 (2014)].
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6.  A.D. Bruce and R.A. Cowley, Structural Phase Transitions (Taylor & Francis Ltd., London, 1981; Mir, Moscow, 1984).
7.  M.P. Shaskolskaya, Crystallography (Vysshaya Shkola, Moscow, 1984) [in Russian].
8.  T.A. Kontorova and Ya.I. Frenkel, "To the Theory of Plastic Deformation and Twinning," Zh. Eksp. Teor. Fiz. 8, 89-95 (1938).
9.  O.M. Braun and Y.S. Kivshar, The Frenkel-Kontorova Model. Concepts, Methods, and Applications (Springer, New York, 2004).
10.  A.V. Porubov, E.L. Aero and G.A. Maugin, "Two Approaches to Study Essentially Nonlinear and Dispersive Properties of the Internal Structure of Materials," Phys. Rev. E. 79, 046608 (2009).
11.  W. Voigt, Lehrbuch der Kristalphysik (Leipzig, 1910).
12.  C. Kittel, Introdution to Solid State Physics (John Willey and Sons, Inc., New York, 1970; GIFML, Moscow, 1978).
13.  E.L. Aero, A.N. Bulygin and Yu.V. Pavlov, "Functionally Invariant Solutions of Nonlinear Klein-Fock-Gordon Equation," Appl. Math. Comp. 223, 160-166 (2013).
14.  E.L. Aero, A.N. Bulygin and Yu.V. Pavlov, "Mathematical Methods for Solution of Nonlinear Model of Deformation of Crystal Media with Complex Lattice," in Proc. Int. Conference "Days on Diffraction 2015" (SPbGU, St. Petersburg, 2015), pp. 8-13.
15.  E.L. Aero, A.N. Bulygin and Yu.V. Pavlov, "Nonlinear Model of Deformation of Crystal Media with Complex Lattice: Mathematical Methods of Model Implementation," Math. Mech. Sol. 21, 19-36 (2016).
Received 30 April 2017
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