Entanglement gap in 1D long-range quantum spherical models
Abstract
We investigate the finite-size scaling of the entanglement gap in the one dimensional long-range quantum spherical model (QSM). We focus on the weak long-range QSM, for which the thermodynamic limit is well-defined. This model exhibits a continuous phase transition, separating a paramagnetic from a ferromagnet phase. The universality class of the transition depends on the long-range exponent . We show that in the thermodynamic limit the entanglement gap is finite in the paramagnetic phase, and it vanishes in the ferromagnetic phase. In the ferromagnetic phase the entanglement gap is understood in terms of standard magnetic correlation functions. The entanglement gap decays as , where the constant depends on the low-energy properties of the model. This reflects that the lower part of the dispersion is affected by the long range physics. Finally, multiplicative logarithmic corrections are absent in the scaling of the entanglement gap, in contrast with the higher-dimensional case.
Keywords
Cite
@article{arxiv.2301.09143,
title = {Entanglement gap in 1D long-range quantum spherical models},
author = {Sascha Wald and Raul Arias and Vincenzo Alba},
journal= {arXiv preprint arXiv:2301.09143},
year = {2023}
}
Comments
35 pages, 4 appendices, 7+3 figures. Minor modifications. Added one figure. Similar to published version