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Main Authors: Voinea, Cristian, Pu, Songyang, Kirmani, Ammar, Ghaemi, Pouyan, Rahmani, Armin, Papić, Zlatko
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2309.04527
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author Voinea, Cristian
Pu, Songyang
Kirmani, Ammar
Ghaemi, Pouyan
Rahmani, Armin
Papić, Zlatko
author_facet Voinea, Cristian
Pu, Songyang
Kirmani, Ammar
Ghaemi, Pouyan
Rahmani, Armin
Papić, Zlatko
contents We propose a frustration-free model for the Moore-Read quantum Hall state on sufficiently thin cylinders with circumferences $\lesssim 7$ magnetic lengths. While the Moore-Read Hamiltonian involves complicated long-range interactions between triplets of electrons in a Landau level, our effective model is a simpler one-dimensional chain of qubits with deformed Fredkin gates. We show that the ground state of the Fredkin model has high overlap with the Moore-Read wave function and accurately reproduces the latter's entanglement properties. Moreover, we demonstrate that the model captures the dynamical response of the Moore-Read state to a geometric quench, induced by suddenly changing the anisotropy of the system. We elucidate the underlying mechanism of the quench dynamics and show that it coincides with the linearized bimetric field theory. The minimal model introduced here can be directly implemented as a first step towards quantum simulation of the Moore-Read state, as we demonstrate by deriving an efficient circuit approximation to the ground state and implementing it on IBM quantum processor.
format Preprint
id arxiv_https___arxiv_org_abs_2309_04527
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Deformed Fredkin model for the $ν{=}5/2$ Moore-Read state on thin cylinders
Voinea, Cristian
Pu, Songyang
Kirmani, Ammar
Ghaemi, Pouyan
Rahmani, Armin
Papić, Zlatko
Strongly Correlated Electrons
Mesoscale and Nanoscale Physics
Quantum Physics
We propose a frustration-free model for the Moore-Read quantum Hall state on sufficiently thin cylinders with circumferences $\lesssim 7$ magnetic lengths. While the Moore-Read Hamiltonian involves complicated long-range interactions between triplets of electrons in a Landau level, our effective model is a simpler one-dimensional chain of qubits with deformed Fredkin gates. We show that the ground state of the Fredkin model has high overlap with the Moore-Read wave function and accurately reproduces the latter's entanglement properties. Moreover, we demonstrate that the model captures the dynamical response of the Moore-Read state to a geometric quench, induced by suddenly changing the anisotropy of the system. We elucidate the underlying mechanism of the quench dynamics and show that it coincides with the linearized bimetric field theory. The minimal model introduced here can be directly implemented as a first step towards quantum simulation of the Moore-Read state, as we demonstrate by deriving an efficient circuit approximation to the ground state and implementing it on IBM quantum processor.
title Deformed Fredkin model for the $ν{=}5/2$ Moore-Read state on thin cylinders
topic Strongly Correlated Electrons
Mesoscale and Nanoscale Physics
Quantum Physics
url https://arxiv.org/abs/2309.04527