Parity violation in atomic ytterbium: experimental sensitivity and systematics

TL;DR

This paper reports the first observation of parity violation in atomic ytterbium, detailing experimental setup, measurements, and systematic corrections, with an emphasis on improving future precision in fundamental symmetry tests.

Contribution

The study provides the first experimental observation of parity violation in ytterbium and analyzes systematic effects affecting measurement accuracy.

Findings

Parity violation observed in ytterbium transition

Systematic corrections quantified and addressed

Experimental uncertainties identified and discussed

Abstract

We present a detailed description of the observation of parity violation in the 1S0-3D1 408-nm forbidden transition of ytterbium, a brief report of which appeared earlier. Linearly polarized 408-nm light interacts with Yb atoms in crossed E- and B-fields. The probability of the 408-nm transition contains a parity violating term, proportional to (Elight . B)[(E x Elight) . B], arising from interference between the parity violating amplitude and the Stark amplitude due to the E-field (Elight is the electric field of the light). The transition probability is detected by measuring the population of the 3P0 state, to which 65% of the atoms excited to the 3D1 state spontaneously decay. The population of the 3P0 state is determined by resonantly exciting the atoms with 649-nm light to the 6s7s 3S1 state and collecting the fluorescence resulting from its decay. Systematic corrections due to E-field and B-field imperfections are determined in auxiliary experiments. The statistical uncertainty is dominated by parasitic frequency excursions of the 408-nm excitation light due to imperfect stabilization of the optical reference with respect to the atomic resonance. The present uncertainties are 9% statistical and 8% systematic. Methods of improving the accuracy for the future experiments are discussed.