Radiative lifetime and energy of the low-energy isomeric level in<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML"><mml:mrow><mml:mmultiscripts><mml:mi mathvariant="normal">Th</mml:mi><mml:mprescripts /><mml:none /><mml:mn>229</mml:mn></mml:mmultiscripts></mml:mrow></mml:math>

Tkalya, E. V.; Schneider, Christian; Jeet, Justin; Hudson, Eric R.

doi:10.1103/physrevc.92.054324

Cited by 86 publications

(49 citation statements)

References 60 publications

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“…The vertical lines in Fig. 3 denote the most recent values for the energy of the nuclear isomeric state, ranging from 7.1 eV to 7.6 eV and 7.8 eV [32,39,40]. The grey shaded area denotes the combined uncertainties of all three measurements and, thus, a recommended initial search area for the nuclear isomer.…”

Section: Resultsmentioning

confidence: 99%

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Excitation of the Th229 nucleus via a two-photon electronic transition

2019

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We investigate the process of nuclear excitation via a two-photon electron transition (NETP) for the case of the doubly charged thorium. The theory of the NETP process has been devised originally for heavy helium like ions. In this work we study this process in the nuclear clock isotope 229 Th in the 2+ charge state. For this purpose we employ a combination of configuration interaction and many-body perturbation theory to calculate the probability of NETP in resonance approximation. The experimental scenario we propose for the excitation of the low lying isomeric state in 229 Th is a circular process starting with a two-step pumping stage followed by NETP. The ideal intermediate steps in this process depend on the supposed energy ωN of the nuclear isomeric state. For each of these energies the best initial state for NETP is calculated. Special focus is put on the most recent experimental results for ωN .

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Section: Resultsmentioning

confidence: 99%

“…The nuclear transition amplitudes I e ||M q ||I g are known from elaborate nuclear calculations, e.g. by Minkov and Pálffy [31], where previous estimates by Tkalya et al [32] have been refined.…”

Section: B Resonance Approximationmentioning

confidence: 99%

Excitation of the Th229 nucleus via a two-photon electronic transition

2019

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“…[6,7] Early on, it was realized that this exotic nuclear excitation would have a widespread potential of applications if its ground-state transition could be controlled, for example, by an optical laser excitation. [6,7] Early on, it was realized that this exotic nuclear excitation would have a widespread potential of applications if its ground-state transition could be controlled, for example, by an optical laser excitation.…”

Section: Introductionmentioning

confidence: 99%

Improving Our Knowledge on the ^229mThorium Isomer: Toward a Test Bench for Time Variations of Fundamental Constants

Thirolf

Wense

2019

Annalen der Physik

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For more than four decades, the lowest excitation in the whole landscape of atomic nuclei, the low-lying, isomeric state of 229 Th, the so-called thorium isomer, has challenged physicists of various disciplines. Being a solitaire with its uniquely low excitation energy of <10 eV, its predicted lifetime of a few hours results in an extremely sharp relative linewidth E/E as low as 10 -20 . While until recently the indication of its existence was based only on indirect evidence, its unique properties inspired a multitude of potential applications, like the use of the thorium isomer as a nuclear frequency standard, potentially able to outperform even the best atomic clocks and a sensitivity-enhanced access to potential temporal variations of fundamental constants. The various proposals to exploit the unique properties of 229m Th are presented herein, in particular focusing on its ability to serve as a test bench for time variations of fundamental constants like the fine structure constant.

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“…The large experimental uncertainty of 0.5 eV (corresponding to ≈ 10 nm or ≈ 120 THz) in combination with an expected narrow nuclear resonance of 10 −4 Hz, presents a practical stumbling block for the direct excitation of this nuclear transition using coherent light sources. Moreover, recent studies shed doubt on the accuracy of the current excitation energy [20]. To improve both the accuracy and the precision of the isomer's key observables, a variety of physics techniques are implemented, with one branch focusing on a direct measurement of the electromagnetic deexcitation of 229m Th embedded in a host material.…”

Section: Introductionmentioning

confidence: 99%

Alternative approach to populate and study the Th229 nuclear clock isomer

Verlinde¹,

Kraemer²,

Moens³

et al. 2019

Phys. Rev. C

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A new approach to observe the radiative decay of the 229 Th nuclear isomer, and to determine its energy and radiative lifetime, is presented. Situated at a uniquely low excitation energy, this nuclear state might be a key ingredient for the development of a nuclear clock, a nuclear laser and the search for time variations of the fundamental constants. The isomer's γ decay towards the ground state will be studied with a high-resolution VUV spectrometer after its production by the β decay of 229 Ac. The novel production method presents a number of advantages asserting its competitive nature with respect to the commonly used 233 U α-decay recoil source. In this paper, a feasibility analysis of this new concept, and an experimental investigation of its key ingredients, using a pure 229 Ac ion beam produced at the ISOLDE radioactive beam facility, is reported.

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Radiative lifetime and energy of the low-energy isomeric level inTh229

Cited by 86 publications

References 60 publications

Excitation of the Th229 nucleus via a two-photon electronic transition

Excitation of the Th229 nucleus via a two-photon electronic transition

Improving Our Knowledge on the ^229mThorium Isomer: Toward a Test Bench for Time Variations of Fundamental Constants

Alternative approach to populate and study the Th229 nuclear clock isomer

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Radiative lifetime and energy of the low-energy isomeric level inTh229

Cited by 86 publications

References 60 publications

Excitation of the Th229 nucleus via a two-photon electronic transition

Excitation of the Th229 nucleus via a two-photon electronic transition

Improving Our Knowledge on the 229mThorium Isomer: Toward a Test Bench for Time Variations of Fundamental Constants

Alternative approach to populate and study the Th229 nuclear clock isomer

Contact Info

Product

Resources

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Improving Our Knowledge on the ^229mThorium Isomer: Toward a Test Bench for Time Variations of Fundamental Constants