Microstructure from ferroelastic transitions using strain pseudospin clock models in two and three dimensions: a local mean-field analysis

Abstract

We show how microstructure can arise in first-order ferroelastic structural transitions, in two and three spatial dimensions, through a local meanfield approximation of their pseudospin hamiltonians, that include anisotropic elastic interactions. Such transitions have symmetry-selected physical strains as their NOP-component order parameters, with Landau free energies that have a single zero-strain 'austenite' minimum at high temperatures, and spontaneous-strain 'martensite' minima of NV structural variants at low temperatures. In a reduced description, the strains at Landau minima induce temperature-dependent, clock-like ZNV +1 hamiltonians, with NOP-component strain-pseudospin vectors S pointing to NV + 1 discrete values (including zero). We study elastic texturing in five such first-order structural transitions through a local meanfield approximation of their pseudospin hamiltonians, that include the powerlaw interactions. As a prototype, we consider the two-variant square/rectangle transition, with a one-component, pseudospin taking NV +1 =3 values of S= 0, 1, as in a generalized Blume-Capel model. We then consider transitions with two-component (NOP = 2) pseudospins: the equilateral to centred-rectangle (NV =3); the square to oblique polygon (NV =4); the triangle to oblique (NV =6) transitions; and finally the 3D cubic to tetragonal transition ( NV =3). The local meanfield solutions in 2D and 3D yield oriented domain-walls patterns as from continuous-variable strain dynamics, showing the discrete-variable models capture the essential ferroelastic texturings. Other related hamiltonians illustrate that structural-transitions in materials science can be the source of interesting spin models in statistical mechanics.