Huy Nguyen Le scite author profile

Self-testing is a device independent method which can be used to determine the nature of a physical system or device, without knowing any detail of the inner mechanism or the physical dimension of Hilbert space of the system. The only information required are the number of measurements, number of outputs of each measurement and the statistics of each measurement. Earlier works on self testing restricted either to two parties scenario or multipartite graph states. Here, we construct a method to self-test the three-qubit W state, and show how to extend it to other pure three-qubit states. Our bounds are robust against the inevitable experimental errors.

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Rectification of light in the quantum regime

Dai

Roulet

et al. 2015

Phys. Rev. A

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One of the missing elements for realising an integrated optical circuit is a rectifying device playing the role of an optical diode. A proposal based on a pair of two-level atoms strongly coupled to a one-dimenisonal waveguide showed a promising behavior based on a semi-classical study [Fratini et al., Phys. Rev. Lett. 113, 243601 (2014)]. Our study in the full quantum regime shows that, in such a device, rectification is a purely multi-photon effect. For an input field in a coherent state, rectification reaches up to $70\%$ for the range of power in which one of the two atoms is excited, but not both.Comment: 7 pages, 3 figures, with a typo in Eq. (4) fixe

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Rabi oscillation in a quantum cavity: Markovian and non-Markovian dynamics

Guimond

Roulet

et al. 2016

Phys. Rev. A

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We investigate the Rabi oscillation of an atom placed inside a quantum cavity where each mirror is formed by a chain of atoms trapped near a one-dimensional waveguide. This proposal was studied previously with the use of Markov approximation, where the delay due to the finite travel time of light between the two cavity mirrors is neglected. We show that Rabi oscillation analogous to that obtained with high-finesse classical cavities is achieved only when this travel time is much larger than the time scale that characterizes the superradiant response of the mirrors. Therefore, the delay must be taken into account and the dynamics of the problem is inherently non-Markovian. Parameters of interest such as the Rabi frequency and the cavity loss rate due to photon leakage through the mirrors are obtained.

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Huy Nguyen Le

Robust self-testing of the three-qubitWstate

Rectification of light in the quantum regime

Rabi oscillation in a quantum cavity: Markovian and non-Markovian dynamics

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