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      Gouy phase and quantum interference with cross-Wigner functions for matter-waves

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          Abstract

          The Gouy phase is essential for accurately describing various wave phenomena, ranging from classical electromagnetic waves to matter waves and quantum optics. In this work, we employ phase-space methods based on the cross-Wigner transformation to analyze spatial and temporal interference in the evolution of matter waves characterized initially by a correlated Gaussian wave packet. First, we consider the cross-Wigner of the initial function with its free evolution, and second for the evolution through a double-slit arrangement. Different from the wave function which acquires a global Gouy phase, we find that the cross-Wigner acquires a Gouy phase difference due to different evolution times. The results suggest that temporal like-Gouy phases are important for an accurate description of temporal interference. Furthermore, we propose a technique based on the Wigner function to reconstruct the cross-Wigner from the spatial intensity interference term in a double-slit experiment with matter waves.

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          Tomography of Atom Beams

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            Author and article information

            Journal
            29 December 2023
            Article
            2401.00083
            0457a9d6-fabf-4903-82f5-2a49047ddfcb

            http://creativecommons.org/licenses/by/4.0/

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            quant-ph

            Quantum physics & Field theory
            Quantum physics & Field theory

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