Hyperfine-Resolved Spectroscopy of Dysprosium Monoxide (DyO) for Precision Measurements of the Nuclear Schiff Moment

TL;DR

This study measures the hyperfine structure of dysprosium monoxide (DyO) to support its use in precision tests for new physics related to the nuclear Schiff moment, combining experimental spectroscopy with theoretical calculations.

Contribution

It provides the first detailed hyperfine structure measurements of DyO isotopologues, validating theoretical models and advancing DyO as a candidate for symmetry-violation experiments.

Findings

Hyperfine parameters agree with relativistic quantum chemical calculations.

DyO exhibits suitable properties for optical cycling and quantum control.

Results enable future precision measurements of the nuclear Schiff moment.

Abstract

We perform laser spectroscopy of dysprosium monoxide (DyO) to determine the hyperfine structure of the ground X8 and excited [17.1]7 states in the $^{161}$Dy and $^{163}$Dy isotopologues. These dysprosium nuclei have non-zero nuclear spin and dynamical octupole deformation, which gives them high sensitivity to time-reversal-violating new physics via the nuclear Schiff moment (NSM). The DyO molecule was recently identified as being amenable to optical cycling -- the basis for many laser cooling and quantum control techniques -- which makes it a practical candidate for NSM searches. The measurements reported here are prerequisites to implementing optical cycling, designing precision measurement protocols, and benchmarking calculations of molecular sensitivity to symmetry-violating effects. The measured hyperfine parameters are interpreted using simple molecular orbital diagrams and show excellent agreement with relativistic quantum chemical calculations.