posted on 2023-11-23, 10:26authored byNM Millen, RP Rundle, JH Samson, Todd Tilma, RF Bishop, Mark Everitt
We apply the generalized Wigner function formalism to detect and characterize a range of quantum phase transitions in several cyclic, finite-length, spin-[Formula presented] one-dimensional spin-chain models, viz., the Ising and anisotropic XY models in a transverse field, and the XXZ anisotropic Heisenberg model. We make use of the finite system size to provide an exhaustive exploration of each system's single-site, bipartite and multi-partite correlation functions. In turn, we are able to demonstrate the utility of phase-space techniques in detecting and characterizing first-order, second-order and infinite-order quantum phase transitions, while also enabling an in-depth analysis of the correlations present within critical systems. We also highlight the method's ability to capture other features of spin systems such as ground-state factorization and critical system scaling. Finally, we demonstrate the generalized Wigner function's utility for state verification by determining the state of each system and their constituent sub-systems at points of interest across the quantum phase transitions, enabling interesting features of critical systems to be readily analyzed.
Funding
Leverhulme Trust (United Kingdom) for the award of an Emeritus Fellowship (EM-2020-013)
DTP 2016-2017 Loughborough University
Engineering and Physical Sciences Research Council