Pathways toward a second-generation molecular vibrational clock

ORAL

Abstract

Molecular clocks represent the cutting edge for precision measurements with molecules. We have completed a full systematic evaluation of a vibrational molecular clock at the 10-14 level in the THz regime. Current limitations include scattering-limited lifetimes, and large lattice lightshift systematics in part due to hyperpolarizability. We discuss the path toward an improved molecular clock through increased coherence times and the mitigation of lattice light scattering and two-body collisional loss. Additionally, we discuss tests of ab initio quantum chemistry calculations and the potential for tests of fundamental physics using the molecular clock.

*This work was supported by NSF grant PHY-1911959, AFOSR MURI FA9550-21-1-0069, ONR grant N00014-21-1-2644, a Center for Fundamental Physics grant from the John Templeton Foundation & Northwestern University, the Brown Science Foundation, and the Polish National Science Centre (NCN) grant 2016/20/W/ST4/00314.

Publication: K. H. Leung*, B. Iritani*, E. Tiberi, I. Majewska, M. Borkowski, R. Moszynski, and T. Zelevinsky, A terahertz vibrational molecular clock with systematic uncertainty at the 10^-14 level, Phys. Rev. X, Accepted (2023).

Presenters

  • Brandon Iritani

    • Columbia Univ

Authors

  • Brandon Iritani

    • Columbia Univ

  • Kon H Leung

    • Columbia Univ

  • Emily Tiberi

    • Columbia University

  • Mateusz Borkowski

    • University of Amsterdam

  • Tanya Zelevinsky

    • Columbia University