Tin resonance-ionization schemes for atomic- And nuclear-structure studies

F. P. Gustafsson; C. M. Ricketts; M. L. Reitsma; R. F. Garcia Ruiz; S. W. Bai; J. C. Berengut; J. Billowes; C. L. Binnersley; A. Borschevsky; T. E. Cocolios; B. S. Cooper; R. P. De Groote; K. T. Flanagan; Koszorús; G. Neyens; H. A. Perrett; A. R. Vernon; Q. Wang; S. G. Wilkins; X. F. Yang

doi:10.1103/PhysRevA.102.052812

Tin resonance-ionization schemes for atomic- And nuclear-structure studies

F. P. Gustafsson, C. M. Ricketts, M. L. Reitsma, R. F. Garcia Ruiz, S. W. Bai, J. C. Berengut, J. Billowes, C. L. Binnersley, A. Borschevsky, T. E. Cocolios, B. S. Cooper, R. P. De Groote, K. T. Flanagan, Koszorús, G. Neyens, H. A. Perrett, A. R. Vernon, Q. Wang, S. G. Wilkins, X. F. Yang

High-Energy Frontier

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Abstract

This paper presents high-precision spectroscopic measurements of atomic tin using five different resonance-ionization schemes performed with the collinear resonance-ionization spectroscopy technique. Isotope shifts were measured for the stable tin isotopes from the 5s25p2P0,1,23 and 1S0 to the 5s25p6sP11,P1,23 and 5s25p7s1P1 atomic levels. The magnetic dipole hyperfine constants Ahf have been extracted for six atomic levels with electron angular momentum J>0 from the hyperfine structures of nuclear spin I=1/2 tin isotopes, Sn115,117,119. State-of-the-art atomic calculations using a relativistic Fock-space coupled-cluster method and the configuration interaction approach combined with many-body perturbation theory allow accurate and reliable calculations of both field- and mass-shift factors for the studied transitions, in addition to the hyperfine magnetic fields and electric-field gradients of the atomic levels. The excellent agreement with the experimental results highlights the accuracy of modern atomic theory and establishes an important foundation for precision measurements of nuclear moments and charge radii of the most exotic isotopes of tin.

Original language	English
Article number	052812
Number of pages	13
Journal	Physical Review A
Volume	102
Issue number	5
DOIs	https://doi.org/10.1103/PhysRevA.102.052812
Publication status	Published - 13-Nov-2020

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Gustafsson, F. P., Ricketts, C. M., Reitsma, M. L., Garcia Ruiz, R. F., Bai, S. W., Berengut, J. C., Billowes, J., Binnersley, C. L., Borschevsky, A., Cocolios, T. E., Cooper, B. S., De Groote, R. P., Flanagan, K. T., Koszorús, Neyens, G., Perrett, H. A., Vernon, A. R., Wang, Q., Wilkins, S. G., & Yang, X. F. (2020). Tin resonance-ionization schemes for atomic- And nuclear-structure studies. Physical Review A, 102(5), Article 052812. https://doi.org/10.1103/PhysRevA.102.052812

@article{8dcdcd91d8dd49bc8fb73e31456cd6f1,

title = "Tin resonance-ionization schemes for atomic- And nuclear-structure studies",

abstract = "This paper presents high-precision spectroscopic measurements of atomic tin using five different resonance-ionization schemes performed with the collinear resonance-ionization spectroscopy technique. Isotope shifts were measured for the stable tin isotopes from the 5s25p2P0,1,23 and 1S0 to the 5s25p6sP11,P1,23 and 5s25p7s1P1 atomic levels. The magnetic dipole hyperfine constants Ahf have been extracted for six atomic levels with electron angular momentum J>0 from the hyperfine structures of nuclear spin I=1/2 tin isotopes, Sn115,117,119. State-of-the-art atomic calculations using a relativistic Fock-space coupled-cluster method and the configuration interaction approach combined with many-body perturbation theory allow accurate and reliable calculations of both field- and mass-shift factors for the studied transitions, in addition to the hyperfine magnetic fields and electric-field gradients of the atomic levels. The excellent agreement with the experimental results highlights the accuracy of modern atomic theory and establishes an important foundation for precision measurements of nuclear moments and charge radii of the most exotic isotopes of tin. ",

author = "Gustafsson, \{F. P.\} and Ricketts, \{C. M.\} and Reitsma, \{M. L.\} and \{Garcia Ruiz\}, \{R. F.\} and Bai, \{S. W.\} and Berengut, \{J. C.\} and J. Billowes and Binnersley, \{C. L.\} and A. Borschevsky and Cocolios, \{T. E.\} and Cooper, \{B. S.\} and \{De Groote\}, \{R. P.\} and Flanagan, \{K. T.\} and Koszor{\'u}s and G. Neyens and Perrett, \{H. A.\} and Vernon, \{A. R.\} and Q. Wang and Wilkins, \{S. G.\} and Yang, \{X. F.\}",

note = "Funding Information: This work was supported by ERC Consolidator Grant No. 648381 (FNPMLS); STFC Grants No. ST/L005794/1, No. ST/L005786/1, and No. ST/P004423/1, and Ernest Rutherford Grant No. ST/L002868/1; KU Leuven Grant GOA 15/010 and grants from the FWO (Belgium); the European Unions Grant Agreement No. 654002 (ENSAR2); the U.S. Department of Energy, Office of Science, Office of Nuclear Physics under Grant No. DE-SC0021176; National Key R\&D Program of China (Contract No. 2018YFA0404403), and the National Natural Science Foundation of China (Grant No. 11875073). We would like to thank the Center for Information Technology of the University of Groningen for their support and for providing access to the Peregrine high-performance computing cluster. Publisher Copyright: {\textcopyright} 2020 authors.",

year = "2020",

month = nov,

day = "13",

doi = "10.1103/PhysRevA.102.052812",

language = "English",

volume = "102",

journal = "Physical Review A",

issn = "2469-9926",

publisher = "AMER PHYSICAL SOC",

number = "5",

}

Gustafsson, FP, Ricketts, CM, Reitsma, ML, Garcia Ruiz, RF, Bai, SW, Berengut, JC, Billowes, J, Binnersley, CL, Borschevsky, A, Cocolios, TE, Cooper, BS, De Groote, RP, Flanagan, KT, Koszorús, Neyens, G, Perrett, HA, Vernon, AR, Wang, Q, Wilkins, SG & Yang, XF 2020, 'Tin resonance-ionization schemes for atomic- And nuclear-structure studies', Physical Review A, vol. 102, no. 5, 052812. https://doi.org/10.1103/PhysRevA.102.052812

TY - JOUR

T1 - Tin resonance-ionization schemes for atomic- And nuclear-structure studies

AU - Gustafsson, F. P.

AU - Ricketts, C. M.

AU - Reitsma, M. L.

AU - Garcia Ruiz, R. F.

AU - Bai, S. W.

AU - Berengut, J. C.

AU - Billowes, J.

AU - Binnersley, C. L.

AU - Borschevsky, A.

AU - Cocolios, T. E.

AU - Cooper, B. S.

AU - De Groote, R. P.

AU - Flanagan, K. T.

AU - Koszorús, null

AU - Neyens, G.

AU - Perrett, H. A.

AU - Vernon, A. R.

AU - Wang, Q.

AU - Wilkins, S. G.

AU - Yang, X. F.

N1 - Funding Information: This work was supported by ERC Consolidator Grant No. 648381 (FNPMLS); STFC Grants No. ST/L005794/1, No. ST/L005786/1, and No. ST/P004423/1, and Ernest Rutherford Grant No. ST/L002868/1; KU Leuven Grant GOA 15/010 and grants from the FWO (Belgium); the European Unions Grant Agreement No. 654002 (ENSAR2); the U.S. Department of Energy, Office of Science, Office of Nuclear Physics under Grant No. DE-SC0021176; National Key R&D Program of China (Contract No. 2018YFA0404403), and the National Natural Science Foundation of China (Grant No. 11875073). We would like to thank the Center for Information Technology of the University of Groningen for their support and for providing access to the Peregrine high-performance computing cluster. Publisher Copyright: © 2020 authors.

PY - 2020/11/13

Y1 - 2020/11/13

N2 - This paper presents high-precision spectroscopic measurements of atomic tin using five different resonance-ionization schemes performed with the collinear resonance-ionization spectroscopy technique. Isotope shifts were measured for the stable tin isotopes from the 5s25p2P0,1,23 and 1S0 to the 5s25p6sP11,P1,23 and 5s25p7s1P1 atomic levels. The magnetic dipole hyperfine constants Ahf have been extracted for six atomic levels with electron angular momentum J>0 from the hyperfine structures of nuclear spin I=1/2 tin isotopes, Sn115,117,119. State-of-the-art atomic calculations using a relativistic Fock-space coupled-cluster method and the configuration interaction approach combined with many-body perturbation theory allow accurate and reliable calculations of both field- and mass-shift factors for the studied transitions, in addition to the hyperfine magnetic fields and electric-field gradients of the atomic levels. The excellent agreement with the experimental results highlights the accuracy of modern atomic theory and establishes an important foundation for precision measurements of nuclear moments and charge radii of the most exotic isotopes of tin.

AB - This paper presents high-precision spectroscopic measurements of atomic tin using five different resonance-ionization schemes performed with the collinear resonance-ionization spectroscopy technique. Isotope shifts were measured for the stable tin isotopes from the 5s25p2P0,1,23 and 1S0 to the 5s25p6sP11,P1,23 and 5s25p7s1P1 atomic levels. The magnetic dipole hyperfine constants Ahf have been extracted for six atomic levels with electron angular momentum J>0 from the hyperfine structures of nuclear spin I=1/2 tin isotopes, Sn115,117,119. State-of-the-art atomic calculations using a relativistic Fock-space coupled-cluster method and the configuration interaction approach combined with many-body perturbation theory allow accurate and reliable calculations of both field- and mass-shift factors for the studied transitions, in addition to the hyperfine magnetic fields and electric-field gradients of the atomic levels. The excellent agreement with the experimental results highlights the accuracy of modern atomic theory and establishes an important foundation for precision measurements of nuclear moments and charge radii of the most exotic isotopes of tin.

UR - https://www.scopus.com/pages/publications/85096964840

U2 - 10.1103/PhysRevA.102.052812

DO - 10.1103/PhysRevA.102.052812

M3 - Article

AN - SCOPUS:85096964840

SN - 2469-9926

VL - 102

JO - Physical Review A

JF - Physical Review A

IS - 5

M1 - 052812

ER -

Tin resonance-ionization schemes for atomic- And nuclear-structure studies

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