Related papers: Foliated order parameter in a fracton phase transition

Foliated order parameter in a fracton phase transition

URL: http://arxiv.org/abs/2206.11958v1
Date: Thu, 23 Jun 2022 20:11:20 GMT
Title: Foliated order parameter in a fracton phase transition
Authors: Mohammad Hossein Zarei, Mohammad Nobakht
Abstract summary: We study phase transition in the X-cube model in the presence of a non-linear perturbation. We show there is a first order quantum phase transition from a type I fracton phase to a magnetized phase. We introduce a non-local order parameter in the form of a foliated operator which can characterize the above phase transition.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Finding suitable indicators for characterizing quantum phase transitions plays an important role in understanding different phases of matter. It is especially important for fracton phases where a combination of topology and fractionalization leads to exotic features not seen in other known quantum phases. In this paper, we consider the above problem by studying phase transition in the X-cube model in the presence of a non-linear perturbation. Using an analysis of the ground state fidelity and identifying a discontinuity in the global entanglement, we show there is a first order quantum phase transition from a type I fracton phase with a highly entangled nature to a magnetized phase. Accordingly, we conclude that the global entanglement, as a measure of the total quantum correlations in the ground state, can well capture certain features of fracton phase transitions. Then, we introduce a non-local order parameter in the form of a foliated operator which can characterize the above phase transition. We particularly show that such an order parameter has a geometric nature which captures specific differences of fracton phases with topological phases. Our study is specifically based on a well-known dual mapping to the classical plaquette Ising model where it shows the importance of such dualities in studying different quantum phases of matter.

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