Telecom-band Hyperentangled Photon Pairs from a Fiber-based Source
- URL: http://arxiv.org/abs/2112.03369v1
- Date: Mon, 6 Dec 2021 21:37:43 GMT
- Title: Telecom-band Hyperentangled Photon Pairs from a Fiber-based Source
- Authors: Changjia Chen, Calvin Xu, Arash Riazi, Eric Y. Zhu, Alexander
Greenwood, Alexey V.Gladyshev, Peter G. Kazansky, Brian T. Kirby, Li Qian
- Abstract summary: We experimentally demonstrate the generation of telecom-band biphotons hyperentangled in both the polarization and frequency DoFs.
The states produced by our hyperentanglement source can enable protocols such as dense coding and high-dimensional quantum key distribution.
- Score: 49.06242674127539
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Hyperentanglement, the simultaneous and independent entanglement of quantum
particles in multiple degrees of freedom, is a powerful resource that can be
harnessed for efficient quantum information processing. In photonic systems,
the two degrees of freedom (DoF) often used to carry quantum and classical
information are polarization and frequency, thanks to their robustness in
transmission, both in free space and in optical fibers. Telecom-band
hyperentangled photons generated in optical fibers are of particular interest
because they are compatible with existing fiber-optic infrastructure, and can
be distributed over fiber networks with minimal loss. Here, we experimentally
demonstrate the generation of telecom-band biphotons hyperentangled in both the
polarization and frequency DoFs using a periodically-poled silica fiber and
observe entanglement concurrences above 0.95 for both polarization and
frequency DOFs. Furthermore, by concatenating a Hong-Ou-Mandel interference
test for frequency entanglement and full state tomography for polarization
entanglement in a single experiment, we can demonstrate simultaneous
entanglement in both the polarization and frequency DOFs. The states produced
by our hyperentanglement source can enable protocols such as dense coding and
high-dimensional quantum key distribution.
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