648 Hilbert space dimensionality in a biphoton frequency comb

K.-C. Chang (1); X. Cheng (1,2); M. C. Sarihan (1); A. Kumar (1); Y.; S. Lee (1); T. Zhong (3); Y.-X. Gong (4); Z. Xie (5); J. H. Shapiro (6); F.; N. C. Wong (6); and C. W. Wong (1) ((1) Fang Lu Mesoscopic Optics; Quantum; Electronics Laboratory; Department of Electrical Engineering; University of; California; Los Angeles; CA; USA) ((2) State Key Laboratory of Information; Photonics; Optical Communications; Beijing University of Posts and; Telecommunications; Beijing; PR China) ((3) Institute for Molecular; Engineering; University of Chicago; Chicago; Illinois; USA) ((4) National; Laboratory of Solid State Microstructures; School of Physics; Nanjing; University; Nanjing; PR China) ((5) National Laboratory of Solid State; Microstructures; School of Electronic Science; Engineering; Nanjing; University; Nanjing; PR China) ((6) Research Laboratory of Electronics,; Massachusetts Institute of Technology; Cambridge; MA; USA)

arXiv:2005.07759·quant-ph·February 17, 2025

648 Hilbert space dimensionality in a biphoton frequency comb

K.-C. Chang (1), X. Cheng (1,2), M. C. Sarihan (1), A. Kumar (1), Y., S. Lee (1), T. Zhong (3), Y.-X. Gong (4), Z. Xie (5), J. H. Shapiro (6), F., N. C. Wong (6), and C. W. Wong (1) ((1) Fang Lu Mesoscopic Optics, Quantum, Electronics Laboratory

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TL;DR

This paper demonstrates a biphoton frequency comb with a Hilbert space dimensionality of at least 648, enabling high-dimensional quantum entanglement useful for advanced quantum information processing.

Contribution

It introduces a hyperentangled biphoton frequency comb with unprecedented high-dimensional entanglement verified through multiple quantum tests.

Findings

01

Achieved a Hilbert space dimensionality of at least 648.

02

Observed Hong-Ou-Mandel revivals with 61 time-bin recurrences.

03

Demonstrated Bell violation up to 18.5 standard deviations.

Abstract

Qubit entanglement is a valuable resource for quantum information processing, where increasing its dimensionality provides a pathway towards higher capacity and increased error resilience in quantum communications, cluster computation and quantum phase measurements. Time-frequency entanglement, a continuous variable subspace, enables the high-dimensional encoding of multiple qubits per particle, bounded only by the spectral correlation bandwidth and readout timing jitter. Extending from a dimensionality of two in discrete polarization variables, here we demonstrate a hyperentangled, mode-locked, biphoton frequency comb with a time-frequency Hilbert space dimensionality of at least 648. Hong-Ou-Mandel revivals of the biphoton qubits are observed with 61 time-bin recurrences, biphoton joint spectral correlations over 19 frequency-bins, and an overall interference visibility of the…

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Taxonomy

TopicsQuantum Information and Cryptography · Mechanical and Optical Resonators · Advanced Fiber Laser Technologies