Tunable multi-qubit quantum phase gates with high fidelity based on graphene wrapped particle

Tunable multi-qubit quantum phase gates with high fidelity based on graphene wrapped particle

A graphene wrapped dielectric particle has been proposed theoretically to realize tunable multi-qubit quantum phase gates (QPGs) with ultrahigh fidelity. By using a first-principles Green’s function technique, the interactions between quantum emitters mediated by graphene plasmons have been investig...

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Main Authors: Jun Ren, Weixuan Zhang, Bing Yang, Xiangdong Zhang
Format: Article
Language:English
Published: AIP Publishing LLC 2016-11-01
Series:AIP Advances
Online Access:http://dx.doi.org/10.1063/1.4967332
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spelling doaj-16b3f20ee0454d08aaa50ccb2e42d7052020-11-24T22:58:27ZengAIP Publishing LLCAIP Advances2158-32262016-11-01611115007115007-1110.1063/1.4967332019611ADVTunable multi-qubit quantum phase gates with high fidelity based on graphene wrapped particleJun Ren0Weixuan Zhang1Bing Yang2Xiangdong Zhang3School of Physics, Beijing Institute of Technology, 100081 Beijing, ChinaSchool of Physics, Beijing Institute of Technology, 100081 Beijing, ChinaSchool of Physics, Beijing Institute of Technology, 100081 Beijing, ChinaSchool of Physics, Beijing Institute of Technology, 100081 Beijing, ChinaA graphene wrapped dielectric particle has been proposed theoretically to realize tunable multi-qubit quantum phase gates (QPGs) with ultrahigh fidelity. By using a first-principles Green’s function technique, the interactions between quantum emitters mediated by graphene plasmons have been investigated. We find that the spontaneous decay rates of these emitters can be strongly enhanced and controlled by means of the efficient excitations of eigenmodes in graphene. The collective subradiance and superradiance resulting from the graphene-mediated interactions have been predicted. Based on these phenomena, we propose the tunable multi-qubit QPGs. These phase gates have the advantage of sensitive adjustability by changing the Fermi level or the electrostatic gating in graphene, at the same time they possess very high fidelities due to the small dissipation in the graphene monolayer.http://dx.doi.org/10.1063/1.4967332
collection DOAJ
language English
format Article
sources DOAJ
author Jun Ren
Weixuan Zhang
Bing Yang
Xiangdong Zhang
spellingShingle Jun Ren
Weixuan Zhang
Bing Yang
Xiangdong Zhang
Tunable multi-qubit quantum phase gates with high fidelity based on graphene wrapped particle
AIP Advances
author_facet Jun Ren
Weixuan Zhang
Bing Yang
Xiangdong Zhang
author_sort Jun Ren
title Tunable multi-qubit quantum phase gates with high fidelity based on graphene wrapped particle
title_short Tunable multi-qubit quantum phase gates with high fidelity based on graphene wrapped particle
title_full Tunable multi-qubit quantum phase gates with high fidelity based on graphene wrapped particle
title_fullStr Tunable multi-qubit quantum phase gates with high fidelity based on graphene wrapped particle
title_full_unstemmed Tunable multi-qubit quantum phase gates with high fidelity based on graphene wrapped particle
title_sort tunable multi-qubit quantum phase gates with high fidelity based on graphene wrapped particle
publisher AIP Publishing LLC
series AIP Advances
issn 2158-3226
publishDate 2016-11-01
description A graphene wrapped dielectric particle has been proposed theoretically to realize tunable multi-qubit quantum phase gates (QPGs) with ultrahigh fidelity. By using a first-principles Green’s function technique, the interactions between quantum emitters mediated by graphene plasmons have been investigated. We find that the spontaneous decay rates of these emitters can be strongly enhanced and controlled by means of the efficient excitations of eigenmodes in graphene. The collective subradiance and superradiance resulting from the graphene-mediated interactions have been predicted. Based on these phenomena, we propose the tunable multi-qubit QPGs. These phase gates have the advantage of sensitive adjustability by changing the Fermi level or the electrostatic gating in graphene, at the same time they possess very high fidelities due to the small dissipation in the graphene monolayer.
url http://dx.doi.org/10.1063/1.4967332
work_keys_str_mv AT junren tunablemultiqubitquantumphasegateswithhighfidelitybasedongraphenewrappedparticle
AT weixuanzhang tunablemultiqubitquantumphasegateswithhighfidelitybasedongraphenewrappedparticle
AT bingyang tunablemultiqubitquantumphasegateswithhighfidelitybasedongraphenewrappedparticle
AT xiangdongzhang tunablemultiqubitquantumphasegateswithhighfidelitybasedongraphenewrappedparticle
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