Analysis of thermal radiation in ion traps for optical frequency standards

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autorschaft

  • Miroslav Doležal
  • Petr Balling
  • Peter B.R. Nisbet-Jones
  • Steven A. King
  • Jonathan M. Jones
  • Hugh A. Klein
  • Patrick Gill
  • Thomas Lindvall
  • Anders E. Wallin
  • Mikko Merimaa
  • C. Tamm
  • Christian Sanner
  • Nils Huntemann
  • Nils Scharnhorst
  • Ian D. Leroux
  • Piet Oliver Schmidt
  • Tobias Burgermeister
  • Tanja E. Mehlstäubler
  • Ekkehard Peik

Organisationseinheiten

Externe Organisationen

  • Czech Metrology Institute (CMI)
  • National Physical Laboratory
  • VTT Technical Research Centre of Finland Ltd.
  • Physikalisch-Technische Bundesanstalt (PTB)
Forschungs-netzwerk anzeigen

Details

OriginalspracheEnglisch
Aufsatznummer842
FachzeitschriftMetrologia
Jahrgang52
Ausgabenummer6
PublikationsstatusVeröffentlicht - 12 Nov. 2015

Abstract

In many of the high-precision optical frequency standards with trapped atoms or ions that are under development to date, the ac Stark shift induced by thermal radiation leads to a major contribution to the systematic uncertainty. We present an analysis of the inhomogeneous thermal environment experienced by ions in various types of ion traps. Finite element models which allow the determination of the temperature of the trap structure and the temperature of the radiation were developed for five ion trap designs, including operational traps at PTB and NPL and further optimized designs. Models were refined based on comparison with infrared camera measurement until an agreement of better than 10% of the measured temperature rise at critical test points was reached. The effective temperature rises of the radiation seen by the ion range from 0.8 K to 2.1 K at standard working conditions. The corresponding fractional frequency shift uncertainties resulting from the uncertainty in temperature are in the 10-18 range for optical clocks based on the Sr+ and Yb+ E2 transitions, and even lower for Yb+ E3, In+ and Al+. Issues critical for heating of the trap structure and its predictability were identified and design recommendations developed.

ASJC Scopus Sachgebiete

Zitieren

Analysis of thermal radiation in ion traps for optical frequency standards. / Doležal, Miroslav; Balling, Petr; Nisbet-Jones, Peter B.R. et al.
in: Metrologia, Jahrgang 52, Nr. 6, 842, 12.11.2015.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Doležal, M, Balling, P, Nisbet-Jones, PBR, King, SA, Jones, JM, Klein, HA, Gill, P, Lindvall, T, Wallin, AE, Merimaa, M, Tamm, C, Sanner, C, Huntemann, N, Scharnhorst, N, Leroux, ID, Schmidt, PO, Burgermeister, T, Mehlstäubler, TE & Peik, E 2015, 'Analysis of thermal radiation in ion traps for optical frequency standards', Metrologia, Jg. 52, Nr. 6, 842. https://doi.org/10.1088/0026-1394/52/6/842
Doležal, M., Balling, P., Nisbet-Jones, P. B. R., King, S. A., Jones, J. M., Klein, H. A., Gill, P., Lindvall, T., Wallin, A. E., Merimaa, M., Tamm, C., Sanner, C., Huntemann, N., Scharnhorst, N., Leroux, I. D., Schmidt, P. O., Burgermeister, T., Mehlstäubler, T. E., & Peik, E. (2015). Analysis of thermal radiation in ion traps for optical frequency standards. Metrologia, 52(6), Artikel 842. https://doi.org/10.1088/0026-1394/52/6/842
Doležal M, Balling P, Nisbet-Jones PBR, King SA, Jones JM, Klein HA et al. Analysis of thermal radiation in ion traps for optical frequency standards. Metrologia. 2015 Nov 12;52(6):842. doi: 10.1088/0026-1394/52/6/842
Doležal, Miroslav ; Balling, Petr ; Nisbet-Jones, Peter B.R. et al. / Analysis of thermal radiation in ion traps for optical frequency standards. in: Metrologia. 2015 ; Jahrgang 52, Nr. 6.
Download
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abstract = "In many of the high-precision optical frequency standards with trapped atoms or ions that are under development to date, the ac Stark shift induced by thermal radiation leads to a major contribution to the systematic uncertainty. We present an analysis of the inhomogeneous thermal environment experienced by ions in various types of ion traps. Finite element models which allow the determination of the temperature of the trap structure and the temperature of the radiation were developed for five ion trap designs, including operational traps at PTB and NPL and further optimized designs. Models were refined based on comparison with infrared camera measurement until an agreement of better than 10% of the measured temperature rise at critical test points was reached. The effective temperature rises of the radiation seen by the ion range from 0.8 K to 2.1 K at standard working conditions. The corresponding fractional frequency shift uncertainties resulting from the uncertainty in temperature are in the 10-18 range for optical clocks based on the Sr+ and Yb+ E2 transitions, and even lower for Yb+ E3, In+ and Al+. Issues critical for heating of the trap structure and its predictability were identified and design recommendations developed.",
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AU - Doležal, Miroslav

AU - Balling, Petr

AU - Nisbet-Jones, Peter B.R.

AU - King, Steven A.

AU - Jones, Jonathan M.

AU - Klein, Hugh A.

AU - Gill, Patrick

AU - Lindvall, Thomas

AU - Wallin, Anders E.

AU - Merimaa, Mikko

AU - Tamm, C.

AU - Sanner, Christian

AU - Huntemann, Nils

AU - Scharnhorst, Nils

AU - Leroux, Ian D.

AU - Schmidt, Piet Oliver

AU - Burgermeister, Tobias

AU - Mehlstäubler, Tanja E.

AU - Peik, Ekkehard

PY - 2015/11/12

Y1 - 2015/11/12

N2 - In many of the high-precision optical frequency standards with trapped atoms or ions that are under development to date, the ac Stark shift induced by thermal radiation leads to a major contribution to the systematic uncertainty. We present an analysis of the inhomogeneous thermal environment experienced by ions in various types of ion traps. Finite element models which allow the determination of the temperature of the trap structure and the temperature of the radiation were developed for five ion trap designs, including operational traps at PTB and NPL and further optimized designs. Models were refined based on comparison with infrared camera measurement until an agreement of better than 10% of the measured temperature rise at critical test points was reached. The effective temperature rises of the radiation seen by the ion range from 0.8 K to 2.1 K at standard working conditions. The corresponding fractional frequency shift uncertainties resulting from the uncertainty in temperature are in the 10-18 range for optical clocks based on the Sr+ and Yb+ E2 transitions, and even lower for Yb+ E3, In+ and Al+. Issues critical for heating of the trap structure and its predictability were identified and design recommendations developed.

AB - In many of the high-precision optical frequency standards with trapped atoms or ions that are under development to date, the ac Stark shift induced by thermal radiation leads to a major contribution to the systematic uncertainty. We present an analysis of the inhomogeneous thermal environment experienced by ions in various types of ion traps. Finite element models which allow the determination of the temperature of the trap structure and the temperature of the radiation were developed for five ion trap designs, including operational traps at PTB and NPL and further optimized designs. Models were refined based on comparison with infrared camera measurement until an agreement of better than 10% of the measured temperature rise at critical test points was reached. The effective temperature rises of the radiation seen by the ion range from 0.8 K to 2.1 K at standard working conditions. The corresponding fractional frequency shift uncertainties resulting from the uncertainty in temperature are in the 10-18 range for optical clocks based on the Sr+ and Yb+ E2 transitions, and even lower for Yb+ E3, In+ and Al+. Issues critical for heating of the trap structure and its predictability were identified and design recommendations developed.

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KW - ion traps

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VL - 52

JO - Metrologia

JF - Metrologia

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