Research Area 04

Bayesian Statistics

This research direction explores compact, scalable, chip-compatible platforms for frequency-domain quantum information processing.

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Publications in this area

  1. Beyond critical coupling: optimal design considerations for spontaneous four-wave mixing in microring resonators,

    J. M. Lukens, K. V. Myilswamy, A. Miloshevsky, H.-H. Lu.

    Optics Express 34, 2782–2798 (2026).    doi: 10.1364/OE.585584

  2. Revisiting the role of state texture in gate identification and fixed-point resource theories,

    A. C. B. Greenwood, J. M. Lukens, L. Qian, B. T. Kirby.

    arXiv:2602.22496 (2026).    doi: 10.48550/arXiv.2602.22496

  3. High-resolution tunable frequency beamsplitter enabled by an integrated silicon pulse shaper,

    C.-Y. Su, K. Wu, L. M. Cohen, S. Fatema, N. B. Lingaraju, H.-H. Lu, A. M. Weiner, J. M. Lukens, J. D. McKinney.

    arXiv:2601.23028 (2026).    doi: 10.48550/arXiv.2601.23028

  4. A paradigm for universal quantum information processing with integrated acousto-optic frequency beamsplitters,

    J. M. Lukens, J. H. Dallyn, H.-H. Lu, N. I. Wasserbeck, A. J. Graf, M. Gehl, P. S. Davids, N. T. Otterstrom.

    arXiv:2601.06752 (2026)    doi: 10.48550/arXiv.2601.06752

  5. Optimal coupling for spontaneous four-wave mixing in microring resonators,

    J. M. Lukens, K. V. Myilswamy, A. Miloshevsky, H.-H. Lu.

    FTh4B.5, CLEO, Charlotte, NC    doi: 10.1364/TBD

  6. High-purity photon-pair generation from a dual interferometrically coupled SiN microring,

    V. V. Wankhade, J. O. Gerguis, L. M. Cohen, M. Qi, J. M. Lukens, J. D. McKinney.

    FTh4B.3, CLEO, Charlotte, NC    doi: 10.1364/TBD

  7. Cascaded inter-modal acousto-optics in a CMOS-fabricated silicon photonic circuit,

    A. Graf, F. Hubert, P. Davids, M. Gehl, A. L. Starbuck, P. Rakich, J. M. Lukens, N. T. Otterstrom.

    STu2C.1, CLEO, Charlotte, NC    doi: 10.1364/TBD

  8. A multiplexed source of tunably spaced, spectrally pure frequency-encoded photons,

    F. Hubert, L. M. Cohen, S. E. Madaras, N. T. Otterstrom, M. Gehl, J. M. Lukens, P. S. Davids.

    FTu1D.2, CLEO, Charlotte, NC    doi: 10.1364/TBD

  9. Unitary acousto-optic beam splitters for frequency domain quantum information processing,

    J. H. Dallyn, H.-H. Lu, N. I. Wasserbeck, P. S. Davids, J. M. Lukens, N. T. Otterstrom.

    FM1A.8, CLEO, Charlotte, NC    doi: 10.1364/TBD

  10. On-chip pulse shaping of entangled photons,

    K. Wu, L. M. Cohen, K. V. Myilswamy, N. B. Lingaraju, H.-H. Lu, J. M. Lukens, A. M. Weiner.

    Physical Review Research 7, 033015 (2025)    doi: 10.1103/kvcq-4zqc

  11. On-chip frequency-bin quantum photonics,

    K. V. Myilswamy, L. M. Cohen, S. Seshadri, H.-H. Lu, J. M. Lukens.

    Nanophotonics 14, 1879–1894 (2025)    doi: 10.1515/nanoph-2024-0585

  12. 3 GHz-spaced frequency beam splitter using an on-chip pulse shaper,

    C.-Y. Su, K. Wu, L. M. Cohen, S. Fatema, N. B. Lingaraju, H.-H. Lu, A. M. Weiner, J. M. Lukens, J. D. McKinney.

    FF118-1, CLEO, Long Beach, CA    doi: 10.1364/CLEO_FS.2025.FF118_1

  13. Manipulation of narrowband biphoton temporal correlations using an on-chip spectral shaper,

    L. M. Cohen, K. Wu, K. V. Myilswamy, N. B. Lingaraju, H.-H. Lu, J. M. Lukens, A. M. Weiner.

    FF107-2, CLEO, Long Beach, CA    doi: 10.1364/CLEO_FS.2025.FF107_2

  14. CMOS photonic integrated source of ultrabroadband polarization-entangled photons,

    A. Miloshevsky, L. M. Cohen, K. V. Myilswamy, M. Alshowkan, S. Fatema, H.-H. Lu, A. M. Weiner, J. M. Lukens.

    Optica Quantum 2, 254–259 (2024)    doi: 10.1364/opticaq.521418

  15. Foundry-fabricated photonic integrated circuit for flex-grid entanglement distribution,

    A. Miloshevsky, H.-H. Lu, L. M. Cohen, K. V. Myilswamy, S. Fatema, M. Alshowkan, A. M. Weiner, J. M. Lukens.

    JW2A.139, CLEO, Charlotte, NC    doi: 10.1364/CLEO_AT.2024.JW2A.139

  16. Shaping of time-resolved biphoton correlations with a microresonator-based spectral shaper,

    L. M. Cohen, K. Wu, K. V. Myilswamy, N. B. Lingaraju, H.-H. Lu, J. M. Lukens, A. M. Weiner.

    FTu4F.4, CLEO, Charlotte, NC    doi: 10.1364/CLEO_FS.2024.FTu4F.4

  17. CMOS photonic integrated circuit for flex-grid polarization entanglement,

    A. Miloshevsky, H.-H. Lu, L. M. Cohen, K. V. Myilswamy, S. Fatema, M. Alshowkan, A. M. Weiner, J. M. Lukens.

    Tu3C.6, Optical Fiber Communication Conference, San Diego, CA    doi: 10.1364/OFC.2024.Tu3C.6

  18. Time-resolved Hanbury Brown–Twiss interferometry of on-chip biphoton frequency combs using Vernier phase modulation,

    K. V. Myilswamy, S. Seshadri, H.-H. Lu, M. S. Alshaykh, J. Liu, T. J. Kippenberg, A. M. Weiner, J. M. Lukens.

    Physical Review Applied 19, 034019 (2023)    doi: 10.1103/physrevapplied.19.034019

  19. Foundry-fabricated silicon source of broadband polarization entanglement,

    A. Miloshevsky, L. M. Cohen, K. V. Myilswamy, S. Fatema, M. Alshowkan, H.-H. Lu, A. M. Weiner, J. M. Lukens.

    PD5, IEEE Photonics Conference, Orlando, FL    doi: 10.1109/IPC57732.2023.10360784

  20. Modeling integrated quantum frequency processors towards robust quantum networks,

    B. E. Nussbaum, A. J. Pizzimenti, N. B. Lingaraju, H.-H. Lu, J. M. Lukens.

    124460I, SPIE Photonics West, San Francisco, CA    doi: 10.1117/12.2649212

  21. Design methodologies for integrated quantum frequency processors,

    B. E. Nussbaum, A. J. Pizzimenti, N. B. Lingaraju, H.-H. Lu, J. M. Lukens.

    Journal of Lightwave Technology 40, 7648–7657 (2022)    doi: 10.1109/jlt.2022.3192759

  22. Bayesian tomography of high-dimensional on-chip biphoton frequency combs with randomized measurements,

    H.-H. Lu, K. V. Myilswamy, R. S. Bennink, S. Seshadri, M. S. Alshaykh, J. Liu, T. J. Kippenberg, D. E. Leaird, A. M. Weiner, J. M. Lukens.

    Nature Communications 13, 4338 (2022)    doi: 10.1038/s41467-022-31639-z

  23. Modeling integrated quantum frequency processors,

    B. E. Nussbaum, A. J. Pizzimenti, N. B. Lingaraju, H.-H. Lu, J. M. Lukens.

    TuG2.3, IEEE Photonics Conference, Vancouver, Canada    doi: 10.1109/IPC53466.2022.9975677

  24. Time-resolved HBT interferometry of an integrated pulsed biphoton frequency comb,

    S. Seshadri, K. V. Myilswamy, J. Liu, T. J. Kippenberg, A. M. Weiner, J. M. Lukens.

    LM3F.1, Frontiers in Optics, Rochester, NY    doi: 10.1364/LS.2022.LM3F.1

  25. Time-resolved second-order coherence of an integrated biphoton frequency comb,

    K. V. Myilswamy, S. Seshadri, J. Liu, T. J. Kippenberg, A. M. Weiner, J. M. Lukens.

    FTu5A.2, CLEO, San Jose, CA    doi: 10.1364/CLEO_QELS.2022.FTu5A.2

  26. Randomized tomography of on-chip biphoton frequency combs,

    K. V. Myilswamy, H.-H. Lu, S. Seshadri, M. S. Alshaykh, J. Liu, D. E. Leaird, T. J. Kippenberg, A. M. Weiner, J. M. Lukens.

    LM6E.3, Frontiers in Optics    doi: 10.1364/LS.2021.LM6E.3

  27. Quantum optical microcombs,

    M. Kues, C. Reimer, J. M. Lukens, W. J. Munro, A. M. Weiner, D. J. Moss, R. Morandotti.

    Nature Photonics 13, 170–179 (2019)    doi: 10.1038/s41566-019-0363-0

  28. 50-GHz-spaced comb of high-dimensional frequency-bin entangled photons from an on-chip silicon nitride microresonator,

    P. Imany, J. A. Jaramillo-Villegas, O. D. Odele, K. Han, D. E. Leaird, J. M. Lukens, P. Lougovski, M. Qi, A. M. Weiner.

    Optics Express 26, 1825–1840 (2018)    doi: 10.1364/oe.26.001825