PT phase transition in multidimensional quantum systems

TL;DR

This paper investigates PT phase transitions in multidimensional quantum systems with coupled Hamiltonians, demonstrating through numerical analysis that such transitions are robust and occur at specific coupling strengths, extending understanding beyond one-dimensional models.

Contribution

It introduces and analyzes four coupled multidimensional PT-symmetric Hamiltonians, providing evidence that PT phase transitions occur in higher-dimensional systems, not just one-dimensional ones.

Findings

All four models exhibit PT phase transitions.

Transitions occur at specific coupling constants around 0.04 to 0.1.

PT phase transition is a robust phenomenon in multidimensional systems.

Abstract

Non-Hermitian PT-symmetric quantum-mechanical Hamiltonians generally exhibit a phase transition that separates two parametric regions, (i) a region of unbroken PT symmetry in which the eigenvalues are all real, and (ii) a region of broken PT symmetry in which some of the eigenvalues are complex. This transition has recently been observed experimentally in a variety of physical systems. Until now, theoretical studies of the PT phase transition have generally been limited to one-dimensional models. Here, four nontrivial coupled PT-symmetric Hamiltonians, $H=p^2/2+x^2/2+q^2/2+y^2/2+igx^2y$, $H=p^2/2+x^2/2+q^2/2+y^2+igx^2y$, $H=p^2/2+x^2/2+q^2/2+y^2/2+r^2/2+z^2/2+igxyz$, and $H=p^2/2+x^2/2+q^2/2+y^2+r^2/2+3z^2/2+igxyz$ are examined. Based on extensive numerical studies, this paper conjectures that all four models exhibit a phase transition. The transitions are found to occur at $g\approx 0.1$, $g\approx 0.04$, $g\approx 0.1$, and $g\approx 0.05$. These results suggest that the PT phase transition is a robust phenomenon not limited to systems having one degree of freedom.