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Implementation of a 3 x 3 directionally-unbiased linear optical multiport

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arxiv 2106.13473 v1 pith:TJYMDWZQ submitted 2021-06-25 quant-ph physics.optics

Implementation of a 3 x 3 directionally-unbiased linear optical multiport

classification quant-ph physics.optics
keywords opticallineardirectionally-unbiasedlengthmultiportmultiportsquantumcoherence
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Linear optical multiports are widely used in photonic quantum information processing. Naturally, these devices are directionally-biased since photons always propagate from the input ports toward the output ports. Recently, the concept of directionally-unbiased linear optical multiports was proposed. These directionally-unbiased multiports allow photons to propagate along a reverse direction, which can greatly reduce the number of required linear optical elements for complicated linear optical quantum networks. Here, we report an experimental demonstration of a 3 x 3 directionally-unbiased linear optical fiber multiport using an optical tritter and mirrors. Compared to the previous demonstration using bulk optical elements which works only with light sources with a long coherence length, our experimental directionally-unbiased 3 x 3 optical multiport does not require a long coherence length since it provides negligible optical path length differences among all possible optical trajectories. It can be a useful building block for implementing large-scale quantum walks on complex graph networks.

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