Progress toward precise determination of atomic lifetimes using photon echoes

POSTER

Abstract

We review the progress of a photon echo experiment for sensitive measurements of atomic lifetimes. Using short-pulse excitation of atomic rubidium vapor, we have recently reported the most statistically precise measurement of (26.11 ± 0.03) ns for the 52 P3/2 lifetime*. The experiment relies on heterodyne detection and exploits the signal-to-noise ratio of the coherent release of energy along the direction of excitation, which is an exponential decay as a function of pulse separation T, as well as large repetition rates that are feasible in a heated vapor cell. We describe a background subtraction technique for simultaneously recording signal and background pulses at repetition rates of 1MHz. We expect this technique to overcome technical limitations and allow the exploration of systematic effects.

* H. C. Beica et al., Phys. Rev A 101, 033408 (2020)

*Work supported by NSERC, CFI, OIT, OCE and York University

Publication: Development of a Technique for Precise Determination of Atomic Lifetimes Based on Photon Echoes, H. C. Beica, A. Pouliot, P. Dowling, A. Carew, T. Vacheresse, G. Carlse, L. Marmet, A. Kumarakrishnan, Physical Review A, 101, 033408 (2020)

Presenters

  • Thomas Vacheresse

    • York University
    • Department of Physics and Astronomy, York University, Toronto, Ontario, Canada M3J 1P3

Authors

  • Thomas Vacheresse

    • York University
    • Department of Physics and Astronomy, York University, Toronto, Ontario, Canada M3J 1P3

  • Gehrig M Carlse

    • York University

  • Alexander Pouliot

    • York University

  • Hermina C Beica

    • York University

  • Louis Marmet

    • York University

  • A Kumarakrishnan

    • York University