Interplay between Symmetry Breaking and Interactions in a Symmetry Protected Topological Phase

TL;DR

This paper analyzes how boundary conditions and interactions influence the stability of symmetry protected topological phases in a one-dimensional sine-Gordon model, revealing conditions under which these phases remain robust.

Contribution

It demonstrates the stability criteria of SPT phases under boundary symmetry breaking fields and bulk interactions in a solvable 1D model.

Findings

SPT phases characterized by boundary zero-energy states.

Stability of phases depends on boundary field strength and bulk interactions.

Duality symmetry relates trivial and topological phases.

Abstract

We solve the one dimensional massive Thirring model or equivalently the sine-Gordon model in the repulsive regime with general Dirichlet boundary conditions, which are characterized by two boundary fields $\phi_{L,R}$ associated with the left and right boundaries respectively. In the presence of these boundary fields, which explicitly break the charge conjugation symmetry, the system exhibits a duality symmetry which changes the sign of the mass parameter $m_0$ and shifts the values of the boundary fields by $\phi_{L,R}\rightarrow \phi_{L,R}+\pi$. When the mass parameter $m_0<0$ and the boundary fields $\phi_{L,R}=0$, or equivalently due to duality symmetry, when the mass parameter $m_0>0$ and the boundary fields $\phi_{L,R}=\pi$, the system is at a trivial point. Here, the ground state is unique just as in the case of periodic boundary conditions. In contrast, when the mass parameter $m_0<0$ and the boundary fields $\phi_{L,R}=\pi$, and equivalently due to the duality symmetry, when the mass parameter $m_0>0$ and the boundary fields $\phi_{L,R}=0$, the system is at a topological point where it exhibits a symmetry protected topological (SPT) phase, which is characterized by the existence of zero energy bound states at both the boundaries. For a given value of the mass parameter $m_0$, we find that these phases remain stable in the presence of symmetry breaking fields at the boundary, provided they are smaller than certain critical values which depend on the strength of the interactions in the bulk. Hence, we show that the stability of the SPT and trivial phases depends on the interplay of the symmetry breaking boundary field values and the bulk interaction strength.