Showing papers on "Coherence (physics) published in 2022"
01 Jan 2022
TL;DR: In this paper, a complex-valued neural network composed of pseudo-siamese network and generative adversarial net is proposed to detect the presence of quantum features as anomalies.
Abstract: Quantum properties, such as entanglement and coherence, are indispensable resources in various quantum information processing tasks. However, there still lacks an efficient and scalable way to detecting these useful features especially for high-dimensional quantum systems. In this work, we exploit the convexity of normal samples without quantum features and design an unsupervised machine learning method to detect the presence of quantum features as anomalies. Particularly, given the task of entanglement detection, we propose a complex-valued neural network composed of pseudo-siamese network and generative adversarial net, and then train it with only separable states to construct non-linear witnesses for entanglement. It is shown via numerical examples, ranging from 2-qubit to 10-qubit systems, that our network is able to achieve high detection accuracy with above 97.5% on average. Moreover, it is capable of revealing rich structures of entanglement, such as partial entanglement among subsystems. Our results are readily applicable to the detection of other quantum resources such as Bell nonlocality and steerability, indicating that our work could provide a powerful tool to extract quantum features hidden in high-dimensional quantum data.
9 citations
TL;DR: In this paper, a phase-information-free image reconstruction scheme for imaging through opacity under highly coherent illumination was proposed. But, the deconvolution algorithm shows insensitivity to the light coherence since the spatial frequencies of the object are well preserved in the spatial frequency spectrum of the speckle pattern.
6 citations
TL;DR: In this paper, a quantum rotor analysis of the bond-charge interaction extended Bose-Hubbard model is presented, where phase transitions between the normal state and pair bosonic condensation are examined through the lens of the thermal behavior of the two superfluid order parameters and entropy, as well as the impact of bondcharge interaction on the properties of Bose−Einstein condensation in the presence of many-body correlations.
4 citations
TL;DR: In this article, the authors adapt the double-sided Feynman diagrams for the needs of coherent two-dimensional spectroscopy in the nonresonant regime, and analytically calculate the third-order polarization of a two-level and several variants of three-level systems.
1 citations
TL;DR: In this article, the authors consider parameters and possibilities of enhancing the absolute-value limit of the linear refractive index in coherent atomic systems using wave mixing and show that the only parameters that can effectively change the value of the attainable index are the frequencies of the involved transitions.
1 citations
TL;DR: In this article, the effects of non-Hermiticity on quantum coherence via a noisy quantum kicked rotor (NQKR) were studied, where the random noise comes from the fluctuations in kick amplitude at each time.
Abstract: We study the effects of non-Hermiticity on quantum coherence via a noisy quantum kicked rotor (NQKR). The random noise comes from the fluctuations in kick amplitude at each time. The non-Hermitian driving indicates the imaginary kicking potential, representing the environment-induced atom gain and loss. In the absence of gain and loss, the random noise destroys quantum coherence manifesting dynamical localization, which leads to classical diffusion. Interestingly, in the presence of non-Hermitian kicking potential, the occurrence of dynamical localization is highly sensitive to the gain and loss, manifesting the restoration of quantum coherence. Using the inverse participation ratio arguments, we numerically obtain a phase diagram of the classical diffusion and dynamical localization on the parameter plane of noise amplitude and non-Hermitian driving strength. With the help of analysis on the corresponding quasieigenstates, we achieve insight into dynamical localization, and uncover that the origin of the localization is interference between multiple quasi-eigenstates of the quantum kicked rotor. We further propose an experimental scheme to realize the NQKR in a dissipative cold atomic gas, which paves the way for future experimental investigation of an NQKR and its anomalous non-Hermitian properties.
1 citations
TL;DR: In this article, the spectral decomposition is used to separate local currents and distinguish between the intra-and inter-level current correlation contributions to the noise power spectrum of two quantum dots in a T-geometry.
1 citations