English

Fully integrated quantum frequency processor on a silicon chip

Quantum Physics 2026-02-17 v1 Optics

Abstract

Frequency-bin encoding has recently emerged as a powerful approach for photonic quantum information processing, offering high dimensionality, gate-parallelization, and compatibility with existing telecommunication infrastructure. However, its scalable deployment has so far been hindered by the lack of an integrated platform capable of unifying quantum state generation, coherent frequency mixing, and programmable spectral control.\\ Here, we report the first fully integrated quantum frequency processor, monolithically integrating on the same silicon photonic chip a microresonator-based biphoton quantum frequency comb source, a pump-rejection filter, high-speed phase modulators, and a four-channel, line-by-line pulse shaper. We demonstrate key functionalities, such as tunable frequency beamsplitters with success probabilities exceeding 94%94\% and fidelities above 99.9%99.9\%, as well as the ability to synthesize more general single-qubit gates. Finally, we generate and coherently manipulate high-dimensional frequency-bin entangled states entirely on chip, showcasing control over two-photon quantum walks and performing the first on-chip frequency-bin quantum state tomography of a Bell-state with a fidelity of 95.7(3)%95.7(3)\%. By integrating all key functional elements on the same 4×7mm24\times7\,\textrm{mm}^2 chip, with the possibility of scaling to a larger number of modes, our work marks an important step toward large-scale frequency-domain photonic processors for both classical and quantum applications.

Keywords

Cite

@article{arxiv.2602.14240,
  title  = {Fully integrated quantum frequency processor on a silicon chip},
  author = {Sara Congia and Leopold Virot and Elena Rovetta and Antonio Fincato and Frederic Boeuf and Matteo Galli and Daniele Bajoni and Massimo Borghi},
  journal= {arXiv preprint arXiv:2602.14240},
  year   = {2026}
}
R2 v1 2026-07-01T10:37:39.506Z