Kate L. Fenwick, Jonathan Baker, Guillaume S. Thekkadath, Aaron Z. Goldberg, Khabat Heshami, Philip J. Bustard, Duncan England, Frédéric Bouchard, Benjamin Sussman
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Multiphoton interference in a single-spatial-mode quantum walk
Multiphoton interference is crucial to many photonic quantum technologies. In
particular, interference forms the basis of optical quantum information
processing platforms and can lead to significant computational advantages. It
is therefore interesting to study the interference arising from various states
of light in large interferometric networks. Here, we implement a quantum walk
in a highly stable, low-loss, multiport interferometer with up to 24 ultrafast
time bins. This time-bin interferometer comprises a sequence of birefringent
crystals which produce pulses separated by 4.3\,ps, all along a single optical
axis. Ultrafast Kerr gating in an optical fiber is employed to time-demultiplex
the output from the quantum walk. We measure one-, two-, and three-photon
interference arising from various input state combinations, including a
heralded single-photon state, a thermal state, and an attenuated coherent state
at one or more input ports. Our results demonstrate that ultrafast time bins
are a promising platform to observe large-scale multiphoton interference.
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