Preliminary Observation of Parity Nonconservation in Atomic Thallium

Conti, R. S.; Bucksbaum, P. H.; Chu, Steven; Commins, Eugene D.; Hunter, L. R.

doi:10.1103/physrevlett.42.343

Cited by 120 publications

(57 citation statements)

References 16 publications

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“…This potential can mix atomic states of opposite parity, such as a valence electron in S 1/2 and P 1/2 atomic orbitals. This mixing can either be measured by searching for parity violating optical rotation in atomic emission/absorption [114,117], or by looking for interference between the APV induced state mixing and the mixing provided by an external electric field (the Stark-interference method [119]). APV has been measured in a number of atoms [29,116], and comparison to theory gives tests of the standard model at low energies.…”

Section: Parity Violation and Anapole Momentsmentioning

confidence: 99%

The Buffer Gas Beam: An Intense, Cold, and Slow Source for Atoms and Molecules

2012

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Section: Parity Violation and Anapole Momentsmentioning

confidence: 99%

The Buffer Gas Beam: An Intense, Cold, and Slow Source for Atoms and Molecules

2012

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“…The purpose of the electric field is to provide a reference transition amplitude due to Stark-mixing of the same states, interfering with the PV amplitude. In such interference method [11,12], one is measuring the part of the transition probability that is linear in both the reference Stark-induced amplitude and the PV amplitude. In addition to enhancing the PV-dependent signal, employing the Stark-PV interference technique provides for all-important reversals allowing one to separate the PV effects from various sys-tematics.…”

mentioning

confidence: 99%

Observation of a Large Atomic Parity Violation Effect in Ytterbium

et al. 2009

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Atomic parity violation has been observed in the 6s 2 1 S0 → 5d6s 3 D1 408-nm forbidden transition of ytterbium. The parity-violating amplitude is found to be two orders of magnitude larger than in cesium, where the most precise experiments to date have been performed. This is in accordance with theoretical predictions and constitutes the largest atomic parity-violating amplitude yet observed. This also opens the way to future measurements of neutron skins and anapole moments by comparing parity-violating amplitudes for various isotopes and hyperfine components of the transition. has not yet been possible to test an important prediction of the SM concerning the variation of Q W along a chain of isotopes. It has been suggested [4] that rare-earth atoms may be good candidates for APV experiments because they have chains of stable isotopes, and the APV effects may be enhanced due to the proximity of opposite-parity levels. While the accuracy of atomic calculations is unlikely to ever approach that achieved for atoms with a single valence electron, ratios of PV-amplitudes between different isotopes should provide ratios of weak charges, without involving, to first approximation, any atomic-structure calculations.The present experiment is inspired by the prediction [5] supported by further theoretical work of [6,7], that the PV-amplitude in the chosen transition is ≈100 times larger than that in Cs. The motivation for PVexperiments in Yb is probing low-energy nuclear physics by comparing PV-effects on either a chain of naturally occurring Yb isotopes, or in different hyperfine components for the same odd-neutron-number isotope. The ratio of PV amplitudes for two isotopes of the same element is sensitive to the neutron distributions within the nucleus. The difference between PV amplitudes measured on two different hyperfine lines belonging to the same transition is a manifestation of nuclear-spin-dependent APV, which is sensitive to the nuclear anapole moments (see, for example, reviews [8,9]) that arise from weak interactions between the nucleons. As the precision of the experiment increases, a sensitive test of the Standard Model may also become possible [10].Here we report on experimental verification of the predicted PV-amplitude enhancement in Yb using a measurement of the APV amplitude for 174 Yb. The idea of the experiment is to excite the forbidden 408-nm transition ( Fig. 1) with resonant laser light in the presence of a quasi-static electric field. The PVamplitude of this transition arises due to PV-mixing of the 5d6s 3 D 1 and 6s6p 1 P 1 states. The purpose of the electric field is to provide a reference transition amplitude due to Stark-mixing of the same states, interfering with the PV amplitude. In such interference method [11,12], one is measuring the part of the transition probability that is linear in both the reference Stark-induced amplitude and the PV amplitude. In addition to enhancing the PV-dependent signal, employing the Stark-PV interference technique provides for all-important reversals allow...

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“…Extension to hydrogen-like and heliumlike atoms may result in a test of QED calculations, and is presently under active investigation [5]. Second-ly, the M 1 E 1 nd interference occurs in parity violation experiments, like those being performed at present on cesium [6] and thallium [7] in zero magnetic field and also those under investigation on the same elements with the use of a high magnetic field [8,9].…”

Section: 00mentioning

confidence: 99%

“…In this case, they can only appear in the electronic polarization Pe of the excited state, and not in its global population. Besides [1] : in the PV experiment in zero H field performed on Cs [6] and Tl [7], the [1,8] :…”

Section: 00mentioning

confidence: 99%

Possible M1 - E1 interference effects in m1 forbidden transitions with crossed magnetic and electric fields

Bouchiat

Poirier

1982

J. Phys. France

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Résumé. 2014 Abstract. 2014 In this paper we predict new possible M1 -E1 Stark interference effects which should appear in nS -n' S M1 forbidden transitions when a static magnetic field crossed with the static electric field is applied. In particular it becomes possible to measure the ratio M1/E1 Stark directly on the fluorescence intensity. These effects are also of importance for the problem of systematic errors in Parity Violation experiments and give new ways of calibrating the PV signal.

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Preliminary Observation of Parity Nonconservation in Atomic Thallium

Cited by 120 publications

References 16 publications

The Buffer Gas Beam: An Intense, Cold, and Slow Source for Atoms and Molecules

The Buffer Gas Beam: An Intense, Cold, and Slow Source for Atoms and Molecules

Observation of a Large Atomic Parity Violation Effect in Ytterbium

Possible M1 - E1 interference effects in m1 forbidden transitions with crossed magnetic and electric fields

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