OSC Colloquium: Dr. Michael Raymer

    Thursday, November 18, 2021 - 3:30pm - 5:00pm
    Meinel 307

    1630 E. University Blvd.

    3rd Floor lobby and Room 307


    Open to Campus and Public


    OSC Colloquium Lecture presented by Dr. Michael Raymer

    Topic:  Quantum Enhanced Telescopy: Very Long Baseline Interferometric Imaging using Single-Photon States as a Nonlocal Oscillator

    Host:  Dalziel Wilson

    Visit our website for future lecture dates and speaker information: http://www.optics.arizona.edu/news-events/events/colloquium

    For a list of our archived lectures: http://www.optics.arizona.edu/news-events/events/colloquium/archive


    Recent proposals suggest that distributed single photons serving as a ‘nonlocal oscillator’ can outperform weak coherent states as a phase reference for long-baseline interferometric imaging (VLBI) of weak sources. [1, 2] Such nonlocal quantum states distributed between telescopes can, in-principle, surpass the limits of conventional interferometric-based astronomical imaging methods, which are limited by quantum shot noise, signal loss, or the faintness of the imaged objects. In an initial experiment by our group, photon inter­ference between a nonlocal single-photon state and a spectrally single-mode, quasi-thermal source has been implemented, enabling reconstruction of the source spatial distribution with increased usable signal per source photon detected in coincidence with the nonlocal oscillator photon – the first instance of quantum-enhanced sensing in this context. The longer-term goal is to discover the optimal quantum-enhanced protocol to achieve ultimate SNR and telescope resolution of faint astronomical objects.


    [1] D. Gottesman, T. Jennewein, and S. Croke, “Longer-baseline telescopes using quantum repeaters,” Phys. Rev. Lett. 109, 070503 (2012).


    [2] E. T. Khabiboulline, J. Borregaard, K. De Greve, and M. D. Lukin, Quantum-assisted telescope arrays, Phys. Rev. A 100, 022316 (2019).


    Speaker Bio(s): 

    Michael Raymer is a Physics Professor and a Knight Professor of Liberal Arts and Sciences at the University of Oregon. His research is in quantum optics, atomic and molecular physics, and quantum information science. His current research includes the coherent manipulation of single-photon states for use in quantum communication systems and remote sensing, as well as the use of two-photon entangled states for probing the structure and dynamics of molecular systems.

    He graduated in physics and chemistry at the University of California Santa Cruz, and earned a PhD at the University of Colorado Boulder. He held a faculty position at the University of Rochester’s Institute of Optics before moving to UO in 1988. He was the founding Director of the UO’s Center for Optical, Molecular, and Quantum Science. With colleagues, he led a national effort to lobby the US government to support research in quantum information science and technology, leading to passage of the National Quantum Initiative Act in 2018.