Quantum phase transition as an interplay of Kitaev and Ising interactions

TL;DR

This paper investigates the quantum phase transitions resulting from the interplay of Kitaev and Ising interactions on ladder and 2D lattices, revealing topological, symmetry-broken, and classical spin-liquid phases with detailed theoretical and numerical analysis.

Contribution

It provides a comprehensive analysis of the phase diagram, effective theories, and critical properties of Kitaev-Ising models on ladder and 2D lattices, including new insights into topological and classical phases.

Findings

Kitaev ladder hosts a symmetry-protected topological phase.

Identified a topological phase transition described by the transverse field Ising model.

Discovered a 2D topological transition from spin-liquid to ordered phase.

Abstract

We study the interplay between the Kitaev and Ising interactions on both ladder and two dimensional lattices. We show that the ground state of the Kitaev ladder is a symmetry-protected topological (SPT) phase, which is protected by a $\mathbb{Z}_2 \times \mathbb{Z}_2$ symmetry. It is confirmed by the degeneracy of the entanglement spectrum and non-trivial phase factors (inequivalent projective representations of the symmetries), which are obtained within infinite matrix-product representation of numerical density matrix renormalization group. We derive the effective theory to describe the topological phase transition on both ladder and two-dimensional lattices, which is given by the transverse field Ising model with/without next-nearest neighbor coupling. The ladder has three phases, namely, the Kitaev SPT, symmetry broken ferro/antiferromagnetic order and classical spin-liquid. The non-zero quantum critical point and its corresponding central charge are provided by the effective theory, which are in full agreement with the numerical results, i.e., the divergence of entanglement entropy at the critical point, change of the entanglement spectrum degeneracy and a drop in the ground-state fidelity. The central charge of the critical points are either c=1 or c=2, with the magnetization and correlation exponents being 1/4 and 1/2, respectively. In the absence of frustration, the 2D lattice shows a topological phase transition from the $\mathbb{Z}_2$ spin-liquid state to the long-range ordered Ising phase at finite ratio of couplings, while in the presence of frustration, an order-by-disorder transition is induced by the Kitaev term. The 2D classical spin-liquid phase is unstable against the addition of Kitaev term toward an ordered phase before the transition to the $\mathbb{Z}_2$ spin-liquid state.