Using cold atoms, I probe the energy-level intervals between Rydberg states to high spectroscopic precision.The focus of this work is to lay the groundwork for an updated, highly-controlled measurement of the Rydberg constant using circular-state Rydberg atoms, needed to resolve a recent conflict in proton-radius values that arose in 2010 (the so-called ;;proton radius puzzle;;).Toward this end, I have demonstrated a fundamentally-new mechanism with which to drive atomic (Rydberg-Rydberg) transitions, utilizing an inelastic (state-changing) ponderomotive interaction.Until now, the multipole-field interaction has been the sole mechanism on which spectroscopy of atomic transitions has been based.In this work, the state-changing ponderomotive interaction (;;ponderomotive spectroscopy;;) is demonstrated by amplitude-modulating an optical standing wave at a transition resonance of a Rydberg atom.At the core of this new spectroscopic technique is the requirement that the light intensity must be modulated in space within the atomic volume, and in time at the desired atomic transition frequency.A Rydberg atom in a modulated optical lattice is very well-suited for a demonstration of this novel type of spectroscopy.Magic-wavelength conditions of this interaction are also identified, as well as a method to drive transitions at harmonics of the modulation.Both of these features of ponderomotive spectroscopy will be utilized to simultaneously trap and probe Rydberg atoms to perform the Rydberg constant measurement.I also present a high-precision measurement of the quantum defect of a high-angular-momentum state of rubidium, the atomic species that will be used in the Rydberg constant measurement.The quantum defects of high-angular-momentum states are needed to determine the effect of the rubidium core polarizability on the Rydberg constant measurement, which is anticipated to be a leading uncertainty.Finally, I present the background and design work for a measurement of the Rydberg constant specifically tailored to help resolve the proton radius puzzle, thereby completing the major preliminary work needed for the performance of that high-precision measurement.
PDF
download
878987797
028-85220240
