English

Controllable two-photon interference with versatile quantum frequency processor

Quantum Physics 2018-11-09 v1 Optics

Abstract

Quantum information is the next frontier in information science, promising unconditionally secure communications, enhanced channel capacities, and computing capabilities far beyond their classical counterparts. And as quantum information processing devices continue to transition from the lab to the field, the demand for the foundational infrastructure connecting them with each other and their users---the quantum internet---will only increase. Due to the remarkable success of frequency multiplexing and control in the classical internet, quantum information encoding in optical frequency offers an intriguing synergy with state-of-the-art fiber-optic networks. Yet coherent quantum frequency operations prove extremely challenging, due to the difficulties in mixing frequencies efficiently, arbitrarily, in parallel, and with low noise. Here we implement an original approach based on a reconfigurable quantum frequency processor, designed to perform arbitrary manipulations of spectrally encoded qubits. This processor's unique tunability allows us to demonstrate frequency-bin Hong-Ou-Mandel interference with record-high 94% visibility. Furthermore, by incorporating such tunability with our method's natural parallelizability, we synthesize independent quantum frequency gates in the same device, realizing the first high-fidelity flip of spectral correlations on two entangled photons. Compared to quantum frequency mixing approaches based on nonlinear optics, our linear method removes the need for additional pump fields and significantly reduces background noise. Our results demonstrate multiple functionalities in parallel in a single platform, representing a huge step forward for the frequency-multiplexed quantum internet.

Keywords

Cite

@article{arxiv.1803.10712,
  title  = {Controllable two-photon interference with versatile quantum frequency processor},
  author = {Hsuan-Hao Lu and Joseph M. Lukens and Nicholas A. Peters and Brian P. Williams and Andrew M. Weiner and Pavel Lougovski},
  journal= {arXiv preprint arXiv:1803.10712},
  year   = {2018}
}

Comments

21 pages, 5 figures

R2 v1 2026-06-23T01:07:58.242Z