Your search keyword '"Quadrature Measurements"' showing total 4 results

1. Sufficient condition for a quantum state to be genuinely quantum non-Gaussian

Author

L Happ, M A Efremov, H Nha, and W P Schleich

Subjects

Gaussian state, Wigner functions, quantum information, continuous variables, non-Gaussian states, quadrature measurements, Science, Physics, QC1-999

Abstract

We show that the expectation value of the operator $\hat{{ \mathcal O }}\equiv \exp (-c{\hat{x}}^{2})+\exp (-c{\hat{p}}^{2})$ defined by the position and momentum operators $\hat{x}$ and $\hat{p}$ with a positive parameter c can serve as a tool to identify quantum non-Gaussian states, that is states that cannot be represented as a mixture of Gaussian states. Our condition can be readily tested employing a highly efficient homodyne detection which unlike quantum-state tomography requires the measurements of only two orthogonal quadratures. We demonstrate that our method is even able to detect quantum non-Gaussian states with positive–definite Wigner functions. This situation cannot be addressed in terms of the negativity of the phase-space distribution. Moreover, we demonstrate that our condition can characterize quantum non-Gaussianity for the class of superposition states consisting of a vacuum and integer multiples of four photons under more than 50 % signal attenuation.

Published

2018

2. Output field-quadrature measurements and squeezing in ultrastrong cavity-QED

Author

Roberto Stassi, Salvatore Savasta, Luigi Garziano, Bernardo Spagnolo, and Franco Nori

Subjects

quadrature measurements, squeezing, ultrastrong cavity-QED, Science, Physics, QC1-999

Abstract

We study the squeezing of output quadratures of an electro-magnetic field escaping from a resonator coupled to a general quantum system with arbitrary interaction strengths. The generalized theoretical analysis of output squeezing proposed here is valid for all the interaction regimes of cavity-quantum electrodynamics: from the weak to the strong, ultrastrong, and deep coupling regimes. For coupling rates comparable or larger then the cavity resonance frequency, the standard input–output theory for optical cavities fails to calculate the variance of output field-quadratures and predicts a non-negligible amount of output squeezing, even if the system is in its ground state. Here we show that, for arbitrary interaction strength and for general cavity-embedded quantum systems, no squeezing can be found in the output-field quadratures if the system is in its ground state. We also apply the proposed theoretical approach to study the output squeezing produced by: (i) an artificial two-level atom embedded in a coherently-excited cavity; and (ii) a cascade-type three-level system interacting with a cavity field mode. In the latter case the output squeezing arises from the virtual photons of the atom-cavity dressed states. This work extends the possibility of predicting and analyzing the results of continuous-variable optical quantum-state tomography when optical resonators interact very strongly with other quantum systems.

Published

2016

3. Sufficient condition for a quantum state to be genuinely quantum non-Gaussian

Author

Happ, Lucas, Efremov, Maxim A., Nha, Hyunuchul, and Schleich, Wolfgang P.

Subjects

Wigner functions, DDC 530 / Physics, quantum information, non-Gaussian states, DDC 500 / Natural sciences & mathematics, Gaussian quadrature formulas, Quanteninformation, ddc:530, quadrature measurements, ddc:500, continuous variables, Gaussian state

Abstract

We show that the expectation value of the operator Ô ≡ exp (−cx̂²) + exp (−cpˆ²) defined by the position and momentum operators x̂ and pˆ with a positive parameter c can serve as a tool to identify quantum non-Gaussian states, that is states that cannot be represented as a mixture of Gaussian states. Our condition can be readily tested employing a highly efficient homodyne detection which unlike quantum-state tomography requires the measurements of only two orthogonal quadratures. We demonstrate that our method is even able to detect quantum non-Gaussian states with positive–definite Wigner functions. This situation cannot be addressed in terms of the negativity of the phase-space distribution. Moreover, we demonstrate that our condition can characterize quantum non-Gaussianity for the class of superposition states consisting of a vacuum and integer multiples of four photons under more than 50 % signal attenuation., publishedVersion

Published

2018

4. Output Field-Quadrature Measurements and Squeezing in Ultrastrong Cavity-QED

Author

Bernardo Spagnolo, Roberto Stassi, Franco Nori, Luigi Garziano, Salvatore Savasta, Stassi, R, Savasta, S, Garziano, L, Spagnolo, B., and Nori, F

Subjects

Cavity resonance, Settore FIS/02 - Fisica Teorica, Modelli E Metodi Matematici, FOS: Physical sciences, General Physics and Astronomy, Virtual particle, Physics::Optics, 02 engineering and technology, Ultrastrong Cavity-QED, 01 natural sciences, Resonator, 0103 physical sciences, quadrature measurements, squeezing, ultrastrong cavity-QED, Quantum system, 010306 general physics, Quantum, Physics, Quantum Physics, Space Quantization, Quadrature Measurement, 021001 nanoscience & nanotechnology, Quadrature (astronomy), Quantum System, Squeezing, Quantum electrodynamics, Coupling Regime, ComputingMethodologies_DOCUMENTANDTEXTPROCESSING, Noise, Quantum Physics (quant-ph), 0210 nano-technology, Ground state, Quadrature Measurements

Abstract

We study the squeezing of output quadratures of an electro-magnetic field escaping from a resonator coupled to a general quantum system with arbitrary interaction strengths. The generalized theoretical analysis of output squeezing proposed here is valid for all the interaction regimes of cavity-quantum electrodynamics: from the weak to the strong, ultrastrong, and deep coupling regimes. For coupling rates comparable or larger then the cavity resonance frequency, the standard input–output theory for optical cavities fails to calculate the variance of output field-quadratures and predicts a non-negligible amount of output squeezing, even if the system is in its ground state. Here we show that, for arbitrary interaction strength and for general cavity-embedded quantum systems, no squeezing can be found in the output-field quadratures if the system is in its ground state. We also apply the proposed theoretical approach to study the output squeezing produced by: (i) an artificial two-level atom embedded in a coherently-excited cavity; and (ii) a cascade-type three-level system interacting with a cavity field mode. In the latter case the output squeezing arises from the virtual photons of the atom-cavity dressed states. This work extends the possibility of predicting and analyzing the results of continuous- variable optical quantum-state tomography when optical resonators interact very strongly with other quantum systems.

Published

2015