Direct Measurement of the He Magnetic Moments

Overview

Journal Nature

Specialty Science

Date 2022 Jun 8

PMID 35676477

Authors

A Schneider

B Sikora

S Dickopf

M Muller

N S Oreshkina

A Rischka

I A Valuev

S Ulmer

J Walz

Z Harman

C H Keitel

A Mooser

K Blaum

Affiliations

Soon will be listed here.

Abstract

Helium-3 has nowadays become one of the most important candidates for studies in fundamental physics, nuclear and atomic structure, magnetometry and metrology, as well as chemistry and medicine. In particular, He nuclear magnetic resonance (NMR) probes have been proposed as a new standard for absolute magnetometry. This requires a high-accuracy value for the He nuclear magnetic moment, which, however, has so far been determined only indirectly and with a relative precision of 12 parts per billon. Here we investigate the He ground-state hyperfine structure in a Penning trap to directly measure the nuclear g-factor of He [Formula: see text], the zero-field hyperfine splitting [Formula: see text] Hz and the bound electron g-factor [Formula: see text]. The latter is consistent with our theoretical value [Formula: see text] based on parameters and fundamental constants from ref. . Our measured value for the He nuclear g-factor enables determination of the g-factor of the bare nucleus [Formula: see text] via our accurate calculation of the diamagnetic shielding constant [Formula: see text]. This constitutes a direct calibration for He NMR probes and an improvement of the precision by one order of magnitude compared to previous indirect results. The measured zero-field hyperfine splitting improves the precision by two orders of magnitude compared to the previous most precise value and enables us to determine the Zemach radius to [Formula: see text] fm.

Citing Articles

Precision spectroscopy on Be overcomes limitations from nuclear structure.

Dickopf S, Sikora B, Kaiser A, Muller M, Ulmer S, Yerokhin V Nature. 2024; 632(8026):757-761.

PMID: 39143212 PMC: 11338825. DOI: 10.1038/s41586-024-07795-1.

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