Analysis of atomic-clock data to constrain variations of fundamental   constants

Nathaniel Sherrill; Adam O. Parsons; Charles F. A. Baynham; William; Bowden; E. Anne Curtis; Richard Hendricks; Ian R. Hill; Richard Hobson; Helen; S. Margolis; Billy I. Robertson; Marco Schioppo; Krzysztof Szymaniec,; Alexandra Tofful; Jacob Tunesi; Rachel M. Godun; Xavier Calmet

arXiv:2302.04565·physics.atom-ph·December 18, 2023

Analysis of atomic-clock data to constrain variations of fundamental constants

Nathaniel Sherrill, Adam O. Parsons, Charles F. A. Baynham, William, Bowden, E. Anne Curtis, Richard Hendricks, Ian R. Hill, Richard Hobson, Helen, S. Margolis, Billy I. Robertson, Marco Schioppo, Krzysztof Szymaniec,, Alexandra Tofful, Jacob Tunesi, Rachel M. Godun

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Abstract

We present a new framework to study the time variation of fundamental constants in a model-independent way. Model independence implies more free parameters than assumed in previous studies. Using data from atomic clocks based on $^{87}$ Sr, $^{171}$ Yb $^{+}$ and $^{133}$ Cs, we set bounds on parameters controlling the variation of the fine-structure constant, $α$ , and the electron-to-proton mass ratio, $μ$ . We consider variations on timescales ranging from a minute to almost a day. In addition, we use our results to derive some of the tightest limits to date on the parameter space of models of ultralight dark matter and axion-like particles.

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TopicsAtomic and Subatomic Physics Research · Advanced Frequency and Time Standards · Radioactive Decay and Measurement Techniques