The concept of laser-based conversion electron Mössbauer spectroscopy for a precise energy determination of                          229m                         Th

Lars C. von der Wense; Benedict Seiferle; Christian Schneider; Justin Jeet; Ines Amersdorffer; Nicolas Arlt; Florian Zacherl; Raphael Haas; Dennis Renisch; Patrick Mosel; Philip Mosel; Milutin Kovacev; Uwe Morgner; Christoph E. Düllmann; Eric R. Hudson; Peter G. Thirolf

doi:10.1007/s10751-019-1564-0

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Originalsprache	Englisch
Aufsatznummer	23
Fachzeitschrift	Hyperfine Interactions
Jahrgang	240
Ausgabenummer	1
Publikationsstatus	Elektronisch veröffentlicht (E-Pub) - 13 März 2019

Abstract

²²⁹ Th is the only nucleus currently under investigation for the development of a nuclear optical clock (NOC) of ultra-high accuracy. The insufficient knowledge of the first nuclear excitation energy of ²²⁹ Th has so far hindered direct nuclear laser spectroscopy of thorium ions and thus the development of a NOC. Here, a nuclear laser excitation scheme is detailed, which makes use of thorium atoms instead of ions. This concept, besides potentially leading to the first nuclear laser spectroscopy, would determine the isomeric energy to 40 μeV resolution, corresponding to 10 GHz, which is a 10 ⁴ times improvement compared to the current best energy constraint. This would determine the nuclear isomeric energy to a sufficient accuracy to allow for nuclear laser spectroscopy of individual thorium ions in a Paul trap and thus the development of a single-ion nuclear optical clock.

ASJC Scopus Sachgebiete

Physik und Astronomie (insg.)
Atom- und Molekularphysik sowie Optik
Physik und Astronomie (insg.)
Kern- und Hochenergiephysik
Physik und Astronomie (insg.)
Physik der kondensierten Materie
Chemie (insg.)
Physikalische und Theoretische Chemie

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The concept of laser-based conversion electron Mössbauer spectroscopy for a precise energy determination of ^229m Th. / von der Wense, Lars C.; Seiferle, Benedict; Schneider, Christian et al.
in: Hyperfine Interactions, Jahrgang 240, Nr. 1, 23, 13.03.2019.

Publikation: Beitrag in Fachzeitschrift › Artikel › Forschung › Peer-Review

von der Wense, LC, Seiferle, B, Schneider, C, Jeet, J, Amersdorffer, I, Arlt, N, Zacherl, F, Haas, R, Renisch, D, Mosel, P, Mosel, P, Kovacev, M, Morgner, U, Düllmann, CE, Hudson, ER & Thirolf, PG 2019, 'The concept of laser-based conversion electron Mössbauer spectroscopy for a precise energy determination of ^229m Th', Hyperfine Interactions, Jg. 240, Nr. 1, 23. https://doi.org/10.1007/s10751-019-1564-0, https://doi.org/10.48550/arXiv.1904.01245

von der Wense, L. C., Seiferle, B., Schneider, C., Jeet, J., Amersdorffer, I., Arlt, N., Zacherl, F., Haas, R., Renisch, D., Mosel, P., Mosel, P., Kovacev, M., Morgner, U., Düllmann, C. E., Hudson, E. R., & Thirolf, P. G. (2019). The concept of laser-based conversion electron Mössbauer spectroscopy for a precise energy determination of ^229m Th. Hyperfine Interactions, 240(1), Artikel 23. Vorabveröffentlichung online. https://doi.org/10.1007/s10751-019-1564-0, https://doi.org/10.48550/arXiv.1904.01245

von der Wense LC, Seiferle B, Schneider C, Jeet J, Amersdorffer I, Arlt N et al. The concept of laser-based conversion electron Mössbauer spectroscopy for a precise energy determination of ^229m Th. Hyperfine Interactions. 2019 Mär 13;240(1):23. Epub 2019 Mär 13. doi: 10.1007/s10751-019-1564-0, 10.48550/arXiv.1904.01245

von der Wense, Lars C. ; Seiferle, Benedict ; Schneider, Christian et al. / The concept of laser-based conversion electron Mössbauer spectroscopy for a precise energy determination of ^229m Th. in: Hyperfine Interactions. 2019 ; Jahrgang 240, Nr. 1.

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title = "The concept of laser-based conversion electron M{\"o}ssbauer spectroscopy for a precise energy determination of 229m Th",

abstract = "229 Th is the only nucleus currently under investigation for the development of a nuclear optical clock (NOC) of ultra-high accuracy. The insufficient knowledge of the first nuclear excitation energy of 229 Th has so far hindered direct nuclear laser spectroscopy of thorium ions and thus the development of a NOC. Here, a nuclear laser excitation scheme is detailed, which makes use of thorium atoms instead of ions. This concept, besides potentially leading to the first nuclear laser spectroscopy, would determine the isomeric energy to 40 μeV resolution, corresponding to 10 GHz, which is a 10 4 times improvement compared to the current best energy constraint. This would determine the nuclear isomeric energy to a sufficient accuracy to allow for nuclear laser spectroscopy of individual thorium ions in a Paul trap and thus the development of a single-ion nuclear optical clock. ",

keywords = "Nuclear laser spectroscopy, Nuclear optical clock, Thorium-229",

author = "{von der Wense}, {Lars C.} and Benedict Seiferle and Christian Schneider and Justin Jeet and Ines Amersdorffer and Nicolas Arlt and Florian Zacherl and Raphael Haas and Dennis Renisch and Patrick Mosel and Philip Mosel and Milutin Kovacev and Uwe Morgner and D{\"u}llmann, {Christoph E.} and Hudson, {Eric R.} and Thirolf, {Peter G.}",

note = "Funding Information: Acknowledgements We would like to thank S. Stellmer and T. Schumm for discussions and lending of the VUV excimer laser. For discussions we are also grateful to G. Kazakov, A. P{\'a}lffy, J. Weitenberg and E. Peik. This work was supported by DFG (Th956/3-2) and by the European Union{\textquoteright}s Horizon 2020 research and innovation programme under grant agreement 6674732 ”nuClock”. The efforts at UCLA have been supported in part by DARPA (QuASAR program), ARO (W911NF-11-1-0369), NSF (PHY-1205311), NIST PMG (60NANB14D302), RCSA (20112810), and DOE Office of Nuclear Physics, Isotope Programme.",

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T1 - The concept of laser-based conversion electron Mössbauer spectroscopy for a precise energy determination of 229m Th

AU - von der Wense, Lars C.

AU - Seiferle, Benedict

AU - Schneider, Christian

AU - Jeet, Justin

AU - Amersdorffer, Ines

AU - Arlt, Nicolas

AU - Zacherl, Florian

AU - Haas, Raphael

AU - Renisch, Dennis

AU - Mosel, Patrick

AU - Mosel, Philip

AU - Kovacev, Milutin

AU - Morgner, Uwe

AU - Düllmann, Christoph E.

AU - Hudson, Eric R.

AU - Thirolf, Peter G.

N1 - Funding Information: Acknowledgements We would like to thank S. Stellmer and T. Schumm for discussions and lending of the VUV excimer laser. For discussions we are also grateful to G. Kazakov, A. Pálffy, J. Weitenberg and E. Peik. This work was supported by DFG (Th956/3-2) and by the European Union’s Horizon 2020 research and innovation programme under grant agreement 6674732 ”nuClock”. The efforts at UCLA have been supported in part by DARPA (QuASAR program), ARO (W911NF-11-1-0369), NSF (PHY-1205311), NIST PMG (60NANB14D302), RCSA (20112810), and DOE Office of Nuclear Physics, Isotope Programme.

PY - 2019/3/13

Y1 - 2019/3/13

N2 - 229 Th is the only nucleus currently under investigation for the development of a nuclear optical clock (NOC) of ultra-high accuracy. The insufficient knowledge of the first nuclear excitation energy of 229 Th has so far hindered direct nuclear laser spectroscopy of thorium ions and thus the development of a NOC. Here, a nuclear laser excitation scheme is detailed, which makes use of thorium atoms instead of ions. This concept, besides potentially leading to the first nuclear laser spectroscopy, would determine the isomeric energy to 40 μeV resolution, corresponding to 10 GHz, which is a 10 4 times improvement compared to the current best energy constraint. This would determine the nuclear isomeric energy to a sufficient accuracy to allow for nuclear laser spectroscopy of individual thorium ions in a Paul trap and thus the development of a single-ion nuclear optical clock.

AB - 229 Th is the only nucleus currently under investigation for the development of a nuclear optical clock (NOC) of ultra-high accuracy. The insufficient knowledge of the first nuclear excitation energy of 229 Th has so far hindered direct nuclear laser spectroscopy of thorium ions and thus the development of a NOC. Here, a nuclear laser excitation scheme is detailed, which makes use of thorium atoms instead of ions. This concept, besides potentially leading to the first nuclear laser spectroscopy, would determine the isomeric energy to 40 μeV resolution, corresponding to 10 GHz, which is a 10 4 times improvement compared to the current best energy constraint. This would determine the nuclear isomeric energy to a sufficient accuracy to allow for nuclear laser spectroscopy of individual thorium ions in a Paul trap and thus the development of a single-ion nuclear optical clock.

KW - Nuclear laser spectroscopy

KW - Nuclear optical clock

KW - Thorium-229

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DO - 10.1007/s10751-019-1564-0

M3 - Article

AN - SCOPUS:85063086182

VL - 240

JO - Hyperfine Interactions

JF - Hyperfine Interactions

SN - 0304-3843

IS - 1

M1 - 23

ER -

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The concept of laser-based conversion electron Mössbauer spectroscopy for a precise energy determination of ^229m Th

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