Laser spectroscopy measurement of the 2<i>s</i>-hyperfine splitting in lithium-like bismuth

Sánchez, R.; Lochmann, Matthias; Jöhren, Raphael; Andelkovic, Zoran; Anielski, Denis; Botermann, B.; Bußmann, Michael; Dax, A.; Frömmgen, N.; Geppert, Christopher; Hammen, M.; Hannen, V.; Kühl, T.; Litvinov, Yu. A.; López-Coto, R.; Stöhlker, Thomas; Thompson, Richard C.; Vollbrecht, Jonas; Wen, Weiqiang; Weinheimer, C.; Will, E.; Winters, D.; Nörtershäuser, W.

doi:10.1088/1361-6455/aa63a0

Cited by 18 publications

(14 citation statements)

References 42 publications

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“…A measurement of the electron cooler voltage thus provides the required information on β for the Doppler transformation into the ions' rest frame. In our case the cooler voltage was ≈214 kV and a reliable measurement of such a high voltage was not available during the previous beamtime, leading to the dominant systematic uncertainty reported in refs 13, 32. Here, this issue was resolved by an in-situ measurement using an accurate high-voltage divider built at PTB Braunschweig, the German National Metrology Institute33.…”

Section: Methodsmentioning

confidence: 89%

High precision hyperfine measurements in Bismuth challenge bound-state strong-field QED

et al. 2017

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Electrons bound in highly charged heavy ions such as hydrogen-like bismuth 209Bi82+ experience electromagnetic fields that are a million times stronger than in light atoms. Measuring the wavelength of light emitted and absorbed by these ions is therefore a sensitive testing ground for quantum electrodynamical (QED) effects and especially the electron–nucleus interaction under such extreme conditions. However, insufficient knowledge of the nuclear structure has prevented a rigorous test of strong-field QED. Here we present a measurement of the so-called specific difference between the hyperfine splittings in hydrogen-like and lithium-like bismuth 209Bi82+,80+ with a precision that is improved by more than an order of magnitude. Even though this quantity is believed to be largely insensitive to nuclear structure and therefore the most decisive test of QED in the strong magnetic field regime, we find a 7-σ discrepancy compared with the theoretical prediction.

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Section: Methodsmentioning

confidence: 89%

High precision hyperfine measurements in Bismuth challenge bound-state strong-field QED

et al. 2017

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“…The main part of the LIBELLE beam-time in 2014 was spent on the precise determination of the wavelengths of the HFS transitions in 209 Bi 82+ and 209 Bi 80+ . For that purpose the laser wavelength was scanned repeatedly across the respective transitions and a number of dedicated systematics measurements, among others investigating the influence of the electron cooler current or the buncher amplitude on the observed transition wavelength, were performed [4,5]. In addition to this, some runs were recorded in which the laser was fixed to the transition wavelength of either 209 Bi 82+ or 209 Bi 80+ (in the latter case with the optical shutter system in operation) to obtain high statistics data on the lifetime of the states.…”

Section: Beam-time 2014mentioning

confidence: 99%

Lifetimes and g-factors of the HFS states in H-like and Li-like bismuth

Hannen

Vollbrecht

Andelkovic

et al. 2019

J. Phys. B: At. Mol. Opt. Phys.

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The LIBELLE experiment performed at the experimental storage ring (ESR) at the GSI Helmholtz Center for Heavy Ion Research in Darmstadt, Germany, has successfully determined the ground state hyperfine (HFS) splittings in hydrogenlike ( 209 Bi 82+ ) and lithium-like ( 209 Bi 80+ ) bismuth. The study of HFS transitions in highly charged ions enables precision tests of QED in extreme electric and magnetic fields otherwise not attainable in laboratory experiments. Besides the transition wavelengths the time resolved detection of fluorescence photons following the excitation of the ions by a pulsed laser system also allows the extraction of lifetimes of the upper HFS levels and g-factors of the bound 1s and 2s electrons for both charge states. While the lifetime of the upper HFS state in 209 Bi 82+ has already been measured in earlier experiments, an experimental value for lifetime of this state in 209 Bi 80+ is reported for the first time in this work.

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“…Fully-ionised and up to 4-electron ions are routinely produced at energies of about 100 − 400 MeV/u, see, e.g., Refs. [43][44][45][46][47][48][49][50][51][52][53][54].…”

Section: Heavy-ions Storage Ringsmentioning

confidence: 99%

“…Since typical weak lifetimes are longer than about a ms, for their investigations one requires facilities which are capable to store the produced radionuclides in a preserved high charged state for a sufficiently long time. Apart from the recent studies in the Electron Beam Ion Trap (EBIT) at TRIUMF [23,24], very recent measurements of weak decays of fullyionized 49 Cr 24+ , 53 Fe 26+ atoms [25] and the de-excitation of the 94m Ru 44+ isomeric state [26] at the experimental cooler storage ring CSRe at Institute for Modern Physics (IMP), Lanzhou, all other investigations of decays of HCRs were performed in the ESR of GSI [2][3][4]27].…”

Section: Introductionmentioning

confidence: 99%