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Temporal Wheelers delayed-Choice Experiment based on Cold Atomic Quantum Memory

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 نشر من قبل Dongsheng Ding
 تاريخ النشر 2019
  مجال البحث فيزياء
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Nowadays the most intriguing features of wave particle complementarity of single photon is exemplified by the famous Wheelers delayed choice experiment in linear optics, nuclear magnetic resonance and integrated photonic device systems. Studying the wave particle behavior in light and matter interaction at single photon level is challenging and interesting, which gives how single photons complement in light and matter interaction. Here, we demonstrate a Wheelers delayed choice experiment in an interface of light and atomic memory, in which the cold atomic memory makes the heralded single photon divided into a superposition of atomic collective excitation and leaked pulse, thus acting as memory beam splitters. We observe the morphing behavior between particle and wave of a heralded single photon by changing the relative proportion of quantum random number generator, the second memory efficiency, and the relative storage time of two memories. The reported results exhibit the complementarity behavior of single photon under the interface of light atom interaction.



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