Splitting Gibbs Measures for a Periodic Triple Mixed-Spin Ising Model on a Cayley Tree

Abstract

We consider an Ising model on the Cayley tree k of arbitrary order k1 with three spin species of values (12,1,32) distributed deterministically with period three along the generations. Within the framework of splitting Gibbs measures, we derive the exact boundary-law compatibility equations and characterize translation-invariant splitting Gibbs measures (TISGMs) via a finite system of algebraic relations. In the ferromagnetic regime J>0, writing θ=(β J/2), we further reduce the translation-invariant problem to a one-dimensional scalar fixed-point equation x=f(x,θ,k) for a rational map f. We show that f is strictly increasing and obtain an explicit sufficient condition for phase coexistence: if sk(θ)=f'(1,θ,k)-1>0, then x=f(x,θ,k) admits at least three distinct positive solutions, yielding at least three distinct TISGMs and hence a phase transition driven by the periodic inhomogeneity of the spin structure. For the binary tree k=2 we exploit attractiveness to construct plus and minus Gibbs measures as weak limits with extremal boundary conditions, prove that they are TISGMs corresponding to the minimal and maximal fixed points of f(·,θ,2), and show that they are the minimal and maximal Gibbs measures in the natural stochastic order. Finally, we construct the tree-indexed Markov chain associated with a TISGM and apply the Kesten--Stigum criterion to the disordered TISGM, identifying nonempty parameter regions where this measure is non-extremal and reconstruction occurs.