Design Methodologies for Integrated Quantum Frequency Processors

Benjamin E. Nussbaum, Andrew J. Pizzimenti, Navin B. Lingaraju, Hsuan Hao Lu, Joseph M. Lukens

Research output: Contribution to journalArticlepeer-review

6 Scopus citations

Abstract

Frequency-encoded quantum information offers intriguing opportunities for quantum communications and networking, with the quantum frequency processor paradigm - based on electro-optic phase modulators and Fourier-transform pulse shapers - providing a path for scalable construction of quantum gates. Yet all experimental demonstrations to date have relied on discrete fiber-optic components that occupy significant physical space and impart appreciable loss. In this article, we introduce a model for the design of quantum frequency processors comprising microring resonator-based pulse shapers and integrated phase modulators. We estimate the performance of single and parallel frequency-bin Hadamard gates, finding high fidelity values that extend to frequency bins with relatively wide bandwidths. By incorporating multi-order filter designs as well, we explore the limits of tight frequency spacings, a regime extremely difficult to obtain in bulk optics. Overall, our model is general, simple to use, and extendable to other material platforms, providing a much-needed design tool for future frequency processors in integrated photonics.

Original languageEnglish
Pages (from-to)7648-7657
Number of pages10
JournalJournal of Lightwave Technology
Volume40
Issue number23
DOIs
StatePublished - Dec 1 2022

Keywords

  • Quantum computing
  • optical pulse shaping
  • optical resonators
  • phase modulation
  • photonic integrated circuits
  • silicon photonics

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