Tunable chiral spiral phases in a non-Hermitian Ising-Gamma spin chain

TL;DR

This paper investigates how dissipation affects the phase diagram of a non-Hermitian Ising-Gamma spin chain, revealing the emergence of tunable chiral spiral phases and their potential experimental manipulation.

Contribution

It introduces the first analysis of dissipation-induced spiral phases in a non-Hermitian Ising-Gamma model, highlighting controllable chirality and phase transitions.

Findings

Dissipation expands the spiral phase region.

Opposite chiral spiral phases can coexist due to dissipation.

The transition mechanism depends on Gamma interaction strength.

Abstract

We study the influence of dissipation on the Ising-Gamma model. Through observables such as ground-state energy, order parameters, entanglement entropy, etc., we identify each phase region and provide the global phase diagram of the system. The results show that the region of the spiral phase will continuously expand with the increase of dissipation, gradually squeezing the original paramagnetic and antiferromagnetic phase regions. Remarkably, unlike the conservative system, the introduction of dissipation will cause two spiral phases with opposite chiralities to emerge simultaneously in the system, which provides a possibility for the manipulation of spiral chirality in cold atomic experiments. Moreover, we reveal the mechanism of the dependence of the transformation between these two spiral phases with distinct chirality on the strength of the relative coefficient of off-diagonal Gamma interactions in the Ising-Gamma model. Since both the relevant order parameters and dissipation can be well controlled within a detectable range, these phenomena can be observed in ultracold atomic experiments.