Field Induced Chiral Soliton Phase in the Kitaev Spin Chain

Abstract

The bond-dependent Ising interaction present in the Kitaev model has attracted considerable attention. The appearance of an unexpected intermediate phase under a magnetic field is particularly intriguing, and one may wonder if a similar phase occurs in the Kitaev spin chain with alternating x- and y-bond Ising interactions. Previous studies have focused on a transverse field, hz, and reported a direct transition to the polarized state. Here, we investigate phases with arbitrary angle of two longitudinal fields, hx and hy. For a magnetic field applied along the diagonal, hx=hy, the chain remains gapless up to a critical field hc1xy. Surprisingly, above hc1xy it enters an unusual intermediate phase before reaching the polarized state at hc2xy. This phase is characterized by a staggered vector chirality and for periodic boundary conditions, a two-fold degeneracy with a finite gap. For open boundary systems the ground-state exhibits a single soliton, lowering the energy, and gapless excitations. However, the corresponding anti-soliton raises the energy sufficiently that a gap appears for soliton and anti-soliton pairs in periodic systems. An intuitive variational picture is developed describing the soliton phase.