光子减去位移Fock态的非经典性与量子非高斯性

IF 1.1 4区物理与天体物理 Q3 PHYSICS, MULTIDISCIPLINARY

Canadian Journal of Physics Pub Date : 2023-06-07 DOI:10.1139/cjp-2023-0085

Deepak, A. Chatterjee

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引用次数: 0

摘要

本文利用Wigner对数负性、线性熵势、基于偏态信息的测度和量子非高斯性的相对熵等测度，定量研究了减光子位移Fock态\ket{\psi} =a^kD(\alpha) \ket{n}的非经典和量子非高斯特性，其中k为减光子数，n为Fock参数。我们注意到，在位移参数的小范围内，光子数的减少(k)显著地改变了非经典性和量子非高斯性，而Fock参数(n)在位移参数的大范围内则表现出显著的变化。在这方面，Fock参数的作用被发现比光子减法数更强。最后，利用考虑光子损失通道影响的维格纳函数动力学表明，维格纳负性只能通过高效的探测器检测到。

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Nonclassicality versus quantum non-Gaussianity of photon subtracted displaced Fock state

In this paper, a quantitative investigation of the non-classical and quantum non-Gaussian characters of the photon-subtracted displaced Fock state \ket{\psi}=a^kD(\alpha)\ket{n}, where k is the number of photons subtracted, n is Fock parameter, is performed by using a collection of measures like Wigner logarithmic negativity, linear entropy potential, skew information based measure, and relative entropy of quantum non-Gaussianity. It is noticed that the number of photons subtracted (k) changes the nonclassicality and quantum non-Gaussianity in a significant amount in the regime of small values of the displacement parameter whereas the Fock parameter (n) presents a notable change in the large regime of the displacement parameter. In this respect, the role of the Fock parameter is found to be stronger as compared to the photon subtraction number. Finally, the Wigner function dynamics considering the effects of photon loss channel is used to show that the Wigner negativity can only be detected by highly efficient detectors.

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来源期刊

Canadian Journal of Physics 物理-物理：综合

CiteScore

2.30

自引率

8.30%

发文量

审稿时长

1.7 months

期刊介绍： The Canadian Journal of Physics publishes research articles, rapid communications, and review articles that report significant advances in research in physics, including atomic and molecular physics; condensed matter; elementary particles and fields; nuclear physics; gases, fluid dynamics, and plasmas; electromagnetism and optics; mathematical physics; interdisciplinary, classical, and applied physics; relativity and cosmology; physics education research; statistical mechanics and thermodynamics; quantum physics and quantum computing; gravitation and string theory; biophysics; aeronomy and space physics; and astrophysics.