Controlling phase diagram of finite spin-$1/2$ chains by tuning boundary interactions

TL;DR

This paper introduces a controllable quantum spin-1/2 chain model where boundary interactions can tune bulk properties, revealing phase transitions and emergent phases, with potential applications in quantum device development.

Contribution

The work constructs a finite spin chain with boundary tuning that controls bulk quantum phases, demonstrating non-trivial effects and phase diagram modifications.

Findings

Tuning boundary interactions triggers phase transitions.

Emergence of a pseudo-magnet phase controlled by boundary parameters.

Distinct phase diagrams depending on boundary tuning parameter.

Abstract

Searching for simple models that possess non-trivial controlling properties is one of the central tasks in the field of quantum technologies. In this work, we construct a quantum spin-$1/2$ chain of finite size, termed as controllable spin wire (CSW), in which we have $\hat{S}^{z} \hat{S}^{z}$ (Ising) interactions with a transverse field in the bulk, and $\hat{S}^{x} \hat{S}^{z}$ and $\hat{S}^{z} \hat{S}^{z}$ couplings with a canted field on the boundaries. The Hamiltonians on the boundaries, dubbed as tuning Hamiltonians (TH's), bear the same form as the effective Hamiltonians emerging in the so-called `quantum entanglement simulator' that is originally proposed for mimicking infinite models. We show that tuning the TH's (parametrized by $\alpha$) can trigger non-trivial controlling of the bulk properties, including the degeneracy of energy/entanglement spectra, and the response to the magnetic field $h_{bulk}$ in the bulk. A universal point dubbed as $\alpha^s$ emerges. For $\alpha > \alpha^s$, the ground-state diagram versus $h_{bulk}$ consists of three `phases', which are Ne\'eL and polarized phases, and an emergent pseudo-magnet phase, distinguished by entanglement and magnetization. For $\alpha < \alpha^s$, the phase diagram changes completely, with no step-like behaviors to distinguish phases. Due to its controlling properties and simplicity, the CSW could potentially serve in future the experiments for developing quantum devices.