Scaled free energies, power-law potentials, strain pseudospins and quasi-universality for first-order structural transitions

Abstract

We consider ferroelastic first-order phase transitions with NOP order-parameter strains entering Landau free energies as invariant polynomials, that have NV structural-variant Landau minima. The total free energy includes (seemingly innocuous) harmonic terms, in the n = 6 -NOP non-order-parameter strains. Four 3D transitions are considered, tetragonal/orthorhombic, cubic/tetragonal, cubic/trigonal and cubic/orthorhombic unit-cell distortions, with respectively, NOP = 1, 2, 3 and 2; and NV = 2, 3, 4 and 6. Five 2D transitions are also considered, as simpler examples. Following Barsch and Krumhansl, we scale the free energy to absorb most material-dependent elastic coefficients into an overall prefactor, by scaling in an overall elastic energy density; a dimensionless temperature variable; and the spontaneous-strain magnitude at transition λ <<1. To leading order in λ the scaled Landau minima become material-independent, in a kind of 'quasi-universality'. The scaled minima in NOP-dimensional order-parameter space, fall at the centre and at the NV corners, of a transition-specific polyhedron inscribed in a sphere, whose radius is unity at transition. The `polyhedra' for the four 3D transitions are respectively, a line, a triangle, a tetrahedron, and a hexagon. We minimize the n terms harmonic in the non-order-parameter strains, by substituting solutions of the 'no dislocation' St Venant compatibility constraints, and explicitly obtain powerlaw anisotropic, order-parameter interactions, for all transitions. In a reduced discrete-variable description, the competing minima of the Landau free energies induce unit-magnitude pseudospin vectors, with NV +1 values, pointing to the polyhedra corners and the (zero-value) center.