Extraction of spin-averaged rovibrational transition frequencies in HD$^+$ for the determination of fundamental constants

TL;DR

This paper analyzes high-accuracy rovibrational transition data in HD$^+$ to extract spin-averaged frequencies, aiming to refine fundamental constants like the electron mass and proton-electron mass ratio using theoretical and experimental data.

Contribution

It introduces a comprehensive method combining experimental measurements and theoretical calculations to improve the determination of fundamental constants from HD$^+$ spectroscopy.

Findings

HD$^+$ data can improve the electron relative atomic mass estimate

The analysis refines the proton-electron mass ratio

Combining data with Penning trap measurements enhances accuracy

Abstract

We present a comprehensive analysis of all currently available high-accuracy frequency measurements of rotational and rovibrational transitions in the hydrogen molecular ion HD$^+$. Our analysis utilises the theoretically calculated hyperfine structure to extract the values of three spin-averaged transition frequencies through a global linear least-squares adjustment that takes into account theory-induced correlations between the different transitions. We subsequently use the three spin-averaged transition frequencies as input data in a second adjustment which employs precise theoretical expressions for the transition frequencies, written as a function of the proton, deuteron and electron relative atomic masses, the Rydberg constant, and the proton and deuteron charge radii. Our analysis shows that the HD$^+$ data may significantly improve the value of the electron relative atomic mass and the proton-electron mass ratio, in particular if combined with recent high-precision measurements of particle atomic masses and mass ratios obtained from Penning traps.