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Main Authors: Xavier, Hernan B., Tarabunga, Poetri Sonya, Dalmonte, Marcello, Pereira, Rodrigo G.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2407.21019
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author Xavier, Hernan B.
Tarabunga, Poetri Sonya
Dalmonte, Marcello
Pereira, Rodrigo G.
author_facet Xavier, Hernan B.
Tarabunga, Poetri Sonya
Dalmonte, Marcello
Pereira, Rodrigo G.
contents We study the dynamics of hard-core bosons on ladders, in the presence of strong kinetic constrains akin to those of the Bariev model. We use a combination of analytical methods and numerical simulations to establish the phase diagram of the model. The model displays a paired Tomonaga-Luttinger liquid phase featuring an emergent dipole symmetry, which encodes the local pairing constraint into a global, nonlocal quantity. We scrutinize the effect of such emergent low-energy symmetry during quench dynamics including single-particle defects. We observe that, despite being approximate, the dipole symmetry still leads to very slow relaxation dynamics, which we model via an effective field theory. The model we discuss is amenable to realization in both cold atoms in optical lattices and Rydberg atom arrays with dynamics taking place solely in the Rydberg manifold. To observe the unusual dynamics of excitations in such experimental platforms, we propose a two-step protocol, which starts with the quasi-adiabatic preparation of low-energy states, followed by the local creation of defects and their study under quench dynamics.
format Preprint
id arxiv_https___arxiv_org_abs_2407_21019
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Emergent dipole field theory in atomic ladders
Xavier, Hernan B.
Tarabunga, Poetri Sonya
Dalmonte, Marcello
Pereira, Rodrigo G.
Quantum Gases
Strongly Correlated Electrons
We study the dynamics of hard-core bosons on ladders, in the presence of strong kinetic constrains akin to those of the Bariev model. We use a combination of analytical methods and numerical simulations to establish the phase diagram of the model. The model displays a paired Tomonaga-Luttinger liquid phase featuring an emergent dipole symmetry, which encodes the local pairing constraint into a global, nonlocal quantity. We scrutinize the effect of such emergent low-energy symmetry during quench dynamics including single-particle defects. We observe that, despite being approximate, the dipole symmetry still leads to very slow relaxation dynamics, which we model via an effective field theory. The model we discuss is amenable to realization in both cold atoms in optical lattices and Rydberg atom arrays with dynamics taking place solely in the Rydberg manifold. To observe the unusual dynamics of excitations in such experimental platforms, we propose a two-step protocol, which starts with the quasi-adiabatic preparation of low-energy states, followed by the local creation of defects and their study under quench dynamics.
title Emergent dipole field theory in atomic ladders
topic Quantum Gases
Strongly Correlated Electrons
url https://arxiv.org/abs/2407.21019