Symmetry-protected intermediate trivial phases in quantum spin chains

TL;DR

This paper demonstrates the emergence of symmetry-protected trivial (SPt) phases as intermediate phases in spin-2 quantum chains, using numerical methods and field theory to analyze phase transitions and their connection to SPT phases.

Contribution

It shows that spin-2 chains can host intermediate SPt phases connected to SPT phases, extending previous understanding of phase structures in quantum spin chains.

Findings

Intermediate SPt phases emerge in spin-2 chains.

Transitions between phases are described by conformal field theories with c=1.

Numerical analysis confirms the phase diagram and transition nature.

Abstract

Symmetry-protected trivial (SPt) phases of matter are the product-state analogue of symmetry-protected topological (SPT) phases. This means, SPt phases can be adiabatically connected to a product state by some path that preserves the protecting symmetry. Moreover, SPt and SPT phases can be adiabatically connected to each other when interaction terms that break the symmetries protecting the SPT order are added in the Hamiltonian. It is also known that spin-1 SPT phases in quantum spin chains can emerge as effective intermediate phases of spin-2 Hamiltonians. In this paper we show that a similar scenario is also valid for SPt phases. More precisely, we show that for a given spin-2 quantum chain, effective intermediate spin-1 SPt phases emerge in some regions of the phase diagram, these also being adiabatically connected to non-trivial intermediate SPT phases. We characterize the phase diagram of our model by studying quantities such as the entanglement entropy, symmetry-related order parameters, and 1-site fidelities. Our numerical analysis uses Matrix Product States (MPS) and the infinite Time-Evolving Block Decimation (iTEBD) method to approximate ground states of the system in the thermodynamic limit. Moreover, we provide a field theory description of the possible quantum phase transitions between the SPt phases. Together with the numerical results, such a description shows that the transitions may be described by Conformal Field Theories (CFT) with central charge c=1. Our results are in agreement, and further generalize, those in [Y. Fuji, F. Pollmann, M. Oshikawa, Phys. Rev. Lett. 114, 177204 (2015)].