Quantum Zeno effect in cavity quantum electrodynamics: Experimental proposal with nonideal cavities and detectors

Rossi, R.; Magalhães, A.R. Bosco de; Nemes, M. C.

doi:10.1103/physreva.77.012107

Cited by 6 publications

(4 citation statements)

References 31 publications

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“…ω r , measurement can be seen as a continuous projection and therefore freezes the system dynamics. This effect is well known as the quantum zeno effect [63][64][65][66][67][68][69]. If we match the rates and look at the correlation between measurement time and the rate of incoming photons, we see a saturation at the point when the rate of incoming photons becomes greater than the measurement time, since then the arrival of a photon at the detector during the measurement time is guaranteed (see figure 2(b)).…”

Section: Continuous Inputmentioning

confidence: 97%

“…On the other hand, if γ 1 ≫ ω r , measurement can be seen as a continuous projection and therefore freezes the system dynamics. This effect is well known as the quantum zeno effect [62][63][64][65][66][67][68]. If we match the rates and look at the correlation between measurement time and the rate of incoming photons, we see a saturation at the point…”

Section: A Continuous Inputmentioning

confidence: 98%

See 1 more Smart Citation

Optimizing microwave photodetection: input–output theory

Schöndorf

Govia

Vavilov

et al. 2018

Quantum Sci. Technol.

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High fidelity microwave photon counting is an important tool for various areas from background radiation analysis in astronomy to the implementation of circuit QED architectures for the realization of a scalable quantum information processor. In this work we describe a microwave photon counter coupled to a semi-infinite transmission line. We employ input-output theory to examine a continuously driven transmission line as well as traveling photon wave packets. Using analytic and numerical methods, we calculate the conditions on the system parameters necessary to optimize measurement and achieve high detection efficiency. With this we can derive a general matching condition depending on the different system rates, under which the measurement process is optimal.

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Section: Continuous Inputmentioning

confidence: 97%

Section: A Continuous Inputmentioning

confidence: 98%

Optimizing microwave photodetection: input–output theory

Schöndorf

Govia

Vavilov

et al. 2018

Quantum Sci. Technol.

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show abstract

“…While the entanglement provides undeniable advantages to achieve quantum computers its considerable sensitivity to system-environment interactions, which induces decohering effects in the quantum evolution, is the main impasse to preserve entanglement. Therefor to struggle against the effect of decoherence and to control and maintain the entanglement, various strategies have been proposed, e.g., quantum error correcting codes [5,6,7,8,9], decoherence-free subspaces [10,11,12], weak measurements [13,14,15,16,17], quantum zeno and super zeno effect [18,19,20,21,22] and quantum bang-bang control [23,24,25]. Inspired by refocusing techniques from NMR [26] Vitali et al [25] put forward an interesting practical scheme to control and suppress decoherence using tailored external forcing acting as pulses.…”

Section: Introductionmentioning

confidence: 99%

Anti-symmetry consideration on the preservation of entanglement of spin system

Fasihi

2016

Annals of Physics

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In this work we offer an approach to protect the entanglement based on the anti-symmetric property of the hamiltonian. Our main objective is to protect the entanglement of a given initial three-qubit state which is governed by hamiltonian of a three-spin Ising chain in site-dependent transverse fields. We show that according to anti-symmetric property of the hamiltonian with respect to some operators mimicking the time reversal operator, the dynamics of the system can be effectively reversed. It equips us to control the dynamics of the system. The control procedure is implemented as a sequence of cyclic evolution; accordingly the entanglement of the system is protected for any given initial state with any desired accuracy an long-time. Using this approach we could control not only the multiparty entanglement but also the pairwise entanglement. It is also notable that in this paper although we restrict ourselves mostly within a three-spin Ising chain in site-dependent transverse fields, our approach could be applicable to any n-qubit spin system models. *

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“…In Ref. [16] the Quantum Zeno effect in a bipartite system, composed of two couple microwave cavities (A and B), is studied. It is shown how to inhibit the transition of a single photon, prepared initially in cavity A, by measuring the number of photons on cavity B.…”

mentioning

confidence: 99%