Peter Hooijschuur scite author profile

Photonic processors are pivotal for both quantum and classical information processing tasks using light. In particular, linear optical quantum information processing requires both large-scale and low-loss programmable photonic processors. In this paper, we report the demonstration of the largest universal quantum photonic processor to date: a low-loss 12-mode fully tunable linear interferometer with all-to-all mode coupling based on stoichiometric silicon nitride waveguides.

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Large-alphabet quantum key distribution using spatially encoded light

Tentrup

Luiten²,

Meer

et al. 2019

New J. Phys.

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Most quantum key distribution protocols using a two-dimensional basis, such as HV polarization as first proposed by Bennett and Brassard in 1984, are limited to a key generation density of 1 bit per photon. We increase this key density by encoding information in the transverse spatial displacement of the used photons. Employing this higher-dimensional Hilbert space together with modern singlephoton-detecting cameras, we demonstrate a proof-of-principle large-alphabet quantum key distribution experiment with 1024 symbols and a shared information between sender and receiver of 7bit per photon.

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Programmable quantum photonic processor based on integrated Silicon Nitride waveguides

Taballione¹,

Meer

Snijders³

et al. 2021

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Experimental demonstration of an efficient, semi-device-independent photonic indistinguishability witness

Meer¹,

Hooijschuur²,

Somhorst³

et al. 2021

Preprint

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Efficient and reliable measurements of photonic indistinguishability are crucial to solidify claims of a quantum advantage in photonics. Existing indistinguishability witnesses may be vulnerable to implementation loopholes, showing the need for a measurement which depends on as few assumptions as possible. Here, we introduce a semi-device-independent witness of photonic indistinguishability and measure it on an integrated photonic processor, certifying three-photon indistinguishability in a way that is insensitive to implementation errors in our processor.

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Demonstration of a photonic indistinguishability witness on a programmable quantum photonic processor

Somhorst

Meer

Hooijschuur

et al. 2022

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