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RAS PhysicsЖурнал экспериментальной и теоретической физики Journal of Experimental and Theoretical Physics

  • ISSN (Print) 0044-4510
  • ISSN (Online) 3034-641X

LASER COOLING OF YTTERBIUM-171 ION WITHOUT MAGNETIC FIELD

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PII
10.31857/S0044451024100122-1
DOI
10.31857/S0044451024100122
Publication type
Article
Status
Published
Authors
O. N Prudnikov
  • Affiliation:
    Institute of Laser Physics, Siberian Branch of the Russian Academy of Sciences
    Novosibirsk State University
Volume/ Edition
Volume 166 / Issue number 4
Pages
556-565
Abstract
A scheme for laser cooling of an 171Yb+ ion in a radio-frequency trap using a three-frequency laser field with its components resonant to optical transitions of the line 2 S1/ 2 → 2P1/ 2, which does not require a magnetic field, is experimentally implemented. The exclusion of the magnetic field in the laser cooling cycle allows for precise control of a weak magnetic field (∼ 10-2 Gs), used for spectroscopy of clock transitions in the optical frequency standard based on a single ytterbium ion, which is important for suppressing frequency shifts associated with the quadratic Zeeman effect.
Keywords
Date of publication
15.10.2024
Year of publication
2024
Number of purchasers
0
Views
110

References

  1. 1. M. A. Nielsen, and I.L. Chuang, Quantum Computation and Quantum Information, Cambridge University Press (2010).
  2. 2. S. Falke, N. Lemke, Ch. Grebing et al., New J. Phys. 16, 073023 (2014).
  3. 3. M. Takamoto, I. Ushijima, N. Ohmae, T. Yahagi, K. Kokado, H. Shinkai, and H. Katori, Nat. Photonics 14, 411 (2020).
  4. 4. W. F. McGrew, X. Zhang, R. J. Fasano, S. A. Schaffer, K. Beloy, D. Nicolodi, R. C. Brown, N. Hinkley, G. Milani, M. Schioppo, T. H. Yoon, and A.D. Ludlow, Nature 564, 87 (2018).
  5. 5. C. W. Chou, D. B. Hume, J. C. J. Koelemeij, D. J. Wineland, and T. Rosenband, Phys. Rev. Lett. 104, 070802 (2010).
  6. 6. N. Huntemann, C. Sanner, B. Lipphardt, C. Tamm, and E. Peik, Phys. Rev. Lett. 116, 063001 (2016).
  7. 7. Y. Huang, H. Guan, P. Liu, W. Bian, L. Ma, K. Liang, T. Li, and K. Gao, Phys. Rev. Lett. 116, 01300 (2016).
  8. 8. G. Lion, I. Panet, P. Wolf, C. Guerlin, S. Bize, and P. Delva, J. Geodes. 91, 597 (2017).
  9. 9. W. F. McGrew, X. Zhang X, R. J. Fasano, S. A. Schaffer, K. Beloy, D. Nicolodi, R. C. Brown, N. Hinkley, G. Milani, M. Schioppo, T.H. Yoon, and A.D. Ludlow, Nature 564, 87 (2018) .
  10. 10. R. M. Godun, P. B. R. Nisbet-Jones, J. M. Jones, S. A. King, L. A. M. Johnson, H. S. Margolis, K. Szymaniec, S. N. Lea, K. Bongs, and P. Gill, Phys. Rev. Lett. 113, 210801 (2014).
  11. 11. N. Huntemann, B. Lipphardt, C. Tamm, V. Gerginov, S. Weyers, and E. Peik, Phys. Rev. Lett. 113, 210802 (2014).
  12. 12. V. Dzuba, V. V. Flambaum, M. S. Safronova, S. G. Porsev, T. Pruttivarasin, M. A. Hohensee, and H. Haffner, Nature Physics 12, 465 (2016).
  13. 13. C. Sanner, N. Huntemann, R. Lange, C. Tamm, E. Peik, M. S. Safronova and S. G. Porsev, Nature 567, 2048 (2019).
  14. 14. L. S. Dreissen, C.-H. Yeh, H. A. F¨urst, K. C. Grensemann, and T. E. Mehlst¨aubler, Nature Commun. 13, 7314 (2022).
  15. 15. A. Arvanitaki, J. Huang, and K.V. Tilburg, Phys. Rev. D 91, 015015 (2015).
  16. 16. Y.V. Stadnik, and V.V. Flambaum, Phys. Rev. Lett. 115, 201301 (2015).
  17. 17. Chr. Tamm, S. Weyers, B. Lipphardt, and E. Peik, Phys. Rev. A 80, 043403 (2009).
  18. 18. O. N. Prudnikov, S. V. Chepurov, A. A. Lugovoy, K. M. Rumynin, S. N. Kuznetsov, A. V. Taichenachev, V. I. Yudin, and S. N. Bagayev, Quant. Electron. 47, 806 (2017).
  19. 19. S. V. Chepurov, A. A. Lugovoy, O. N. Prudnikov, A. V. Taichenachev, and S. N. Bagayev, Quant. Electron. 49, 412 (2019).
  20. 20. N. Huntemann, M. Okhapkin, B. Lipphardt, S.Weyers, Chr. Tamm, and E. Peik, Phys. Rev. Lett. 108, 090801 (2012).
  21. 21. N. Huntemann, B. Lipphardt, M. Okhapkin, Chr. Tamm, E. Peik, A. V. Taichenachev and V. I. Yudin, Phys. Rev. Lett. 109, 213002 (2012).
  22. 22. M. A. Aksenov, I. V. Zalivako, I. A. Semerikov, A. S. Borisenko, N. V. Semenin, P. L. Sidorov, A. K. Fedorov, K. Yu. Khabarova, and N. N. Kolachevsky, Phys. Rev. A 107, 052612 (2023).
  23. 23. D. S. Krysenko and O. N. Prudnikov, JETP 137, 239 (2023).
  24. 24. O. N. Prudnikov, A. V. Taichenachev, A.M. Tumaikin and V. I. Yudin, JETP 88, 433 (1999).
  25. 25. E. Biemontyz, J-F Dutrieuxz, I. Martinx, and P. Quinetz, J. Phys. B: At. Mol. Opt. Phys. 31, 3321 (1998.)
  26. 26. A. V. Taichenachev, A. M. Tumaikin, V. I. Yudin, and L. Hollberg, Phys. Rev. A 63, 033402 (2001).
  27. 27. A. P. Kulosa, O. N. Prudnikov, D. Vadlejch, H. A. Furst, A. A. Kirpichnikova, A. V. Taichenachev, V. I. Yudin, and T. E. Mehlstaubler, New J. Phys. 25 053008 (2023).
  28. 28. S. V. Chepurov, N. A. Pavlov, A. A. Lugovoy, S. N. Bagayev, and A. V. Taichenachev, Quantum Electronics 51, 473 (2021).
  29. 29. C. A. Schrama, E. Peik, W. W. Smith, and H. Walther, Opt. Comm. 101, 32 (1993).
  30. 30. A. V. Taichenachev, V. I. Yudin, R. Wynands, M. Stahler, J. Kitching, and L. Hollberg, Phys. Rev. A 67, 033810 (2003).
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