Isotope-shift measurements of stable and short-lived lithium isotopes for nuclear-charge-radii determination

W. Nörtershäuser; R. Sánchez; G. Ewald; A. Dax; J. Behr; P. Bricault; B. A. Bushaw; J. Dilling; M. Dombsky; G. W.F. Drake; S. Götte; H. J. Kluge; Th Kühl; J. Lassen; C. D.P. Levy; K. Pachucki; M. Pearson; M. Puchalski; A. Wojtaszek; Z. C. Yan; C. Zimmermann

doi:10.1103/PhysRevA.83.012516

Isotope-shift measurements of stable and short-lived lithium isotopes for nuclear-charge-radii determination

W. Nörtershäuser, R. Sánchez, G. Ewald, A. Dax, J. Behr, P. Bricault, B. A. Bushaw, J. Dilling, M. Dombsky, G. W.F. Drake, S. Götte, H. J. Kluge, Th Kühl, J. Lassen, C. D.P. Levy, K. Pachucki, M. Pearson, M. Puchalski, A. Wojtaszek, Z. C. YanC. Zimmermann

Neutron Sciences Directorate

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56 Scopus citations

Abstract

Changes in the mean square nuclear charge radii along the lithium isotopic chain were determined using a combination of precise isotope shift measurements and theoretical atomic structure calculations. Nuclear charge radii of light elements are of high interest due to the appearance of the nuclear halo phenomenon in this region of the nuclear chart. During the past years we have developed a laser spectroscopic approach to determine the charge radii of lithium isotopes which combines high sensitivity, speed, and accuracy to measure the extremely small field shift of an 8-ms-lifetime isotope with production rates on the order of only 10 000 atoms/s. The method was applied to all bound isotopes of lithium including the two-neutron halo isotope Li11 at the on-line isotope separators at GSI, Darmstadt, Germany, and at TRIUMF, Vancouver, Canada. We describe the laser spectroscopic method in detail, present updated and improved values from theory and experiment, and discuss the results.

Original language	English
Article number	012516
Journal	Physical Review A - Atomic, Molecular, and Optical Physics
Volume	83
Issue number	1
DOIs	https://doi.org/10.1103/PhysRevA.83.012516
State	Published - Jan 31 2011

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Nörtershäuser, W., Sánchez, R., Ewald, G., Dax, A., Behr, J., Bricault, P., Bushaw, B. A., Dilling, J., Dombsky, M., Drake, G. W. F., Götte, S., Kluge, H. J., Kühl, T., Lassen, J., Levy, C. D. P., Pachucki, K., Pearson, M., Puchalski, M., Wojtaszek, A., ... Zimmermann, C. (2011). Isotope-shift measurements of stable and short-lived lithium isotopes for nuclear-charge-radii determination. Physical Review A - Atomic, Molecular, and Optical Physics, 83(1), Article 012516. https://doi.org/10.1103/PhysRevA.83.012516

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title = "Isotope-shift measurements of stable and short-lived lithium isotopes for nuclear-charge-radii determination",

abstract = "Changes in the mean square nuclear charge radii along the lithium isotopic chain were determined using a combination of precise isotope shift measurements and theoretical atomic structure calculations. Nuclear charge radii of light elements are of high interest due to the appearance of the nuclear halo phenomenon in this region of the nuclear chart. During the past years we have developed a laser spectroscopic approach to determine the charge radii of lithium isotopes which combines high sensitivity, speed, and accuracy to measure the extremely small field shift of an 8-ms-lifetime isotope with production rates on the order of only 10 000 atoms/s. The method was applied to all bound isotopes of lithium including the two-neutron halo isotope Li11 at the on-line isotope separators at GSI, Darmstadt, Germany, and at TRIUMF, Vancouver, Canada. We describe the laser spectroscopic method in detail, present updated and improved values from theory and experiment, and discuss the results.",

author = "W. N{\"o}rtersh{\"a}user and R. S{\'a}nchez and G. Ewald and A. Dax and J. Behr and P. Bricault and Bushaw, {B. A.} and J. Dilling and M. Dombsky and Drake, {G. W.F.} and S. G{\"o}tte and Kluge, {H. J.} and Th K{\"u}hl and J. Lassen and Levy, {C. D.P.} and K. Pachucki and M. Pearson and M. Puchalski and A. Wojtaszek and Yan, {Z. C.} and C. Zimmermann",

year = "2011",

month = jan,

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doi = "10.1103/PhysRevA.83.012516",

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Nörtershäuser, W, Sánchez, R, Ewald, G, Dax, A, Behr, J, Bricault, P, Bushaw, BA, Dilling, J, Dombsky, M, Drake, GWF, Götte, S, Kluge, HJ, Kühl, T, Lassen, J, Levy, CDP, Pachucki, K, Pearson, M, Puchalski, M, Wojtaszek, A, Yan, ZC & Zimmermann, C 2011, 'Isotope-shift measurements of stable and short-lived lithium isotopes for nuclear-charge-radii determination', Physical Review A - Atomic, Molecular, and Optical Physics, vol. 83, no. 1, 012516. https://doi.org/10.1103/PhysRevA.83.012516

TY - JOUR

T1 - Isotope-shift measurements of stable and short-lived lithium isotopes for nuclear-charge-radii determination

AU - Nörtershäuser, W.

AU - Sánchez, R.

AU - Ewald, G.

AU - Dax, A.

AU - Behr, J.

AU - Bricault, P.

AU - Bushaw, B. A.

AU - Dilling, J.

AU - Dombsky, M.

AU - Drake, G. W.F.

AU - Götte, S.

AU - Kluge, H. J.

AU - Kühl, Th

AU - Lassen, J.

AU - Levy, C. D.P.

AU - Pachucki, K.

AU - Pearson, M.

AU - Puchalski, M.

AU - Wojtaszek, A.

AU - Yan, Z. C.

AU - Zimmermann, C.

PY - 2011/1/31

Y1 - 2011/1/31

N2 - Changes in the mean square nuclear charge radii along the lithium isotopic chain were determined using a combination of precise isotope shift measurements and theoretical atomic structure calculations. Nuclear charge radii of light elements are of high interest due to the appearance of the nuclear halo phenomenon in this region of the nuclear chart. During the past years we have developed a laser spectroscopic approach to determine the charge radii of lithium isotopes which combines high sensitivity, speed, and accuracy to measure the extremely small field shift of an 8-ms-lifetime isotope with production rates on the order of only 10 000 atoms/s. The method was applied to all bound isotopes of lithium including the two-neutron halo isotope Li11 at the on-line isotope separators at GSI, Darmstadt, Germany, and at TRIUMF, Vancouver, Canada. We describe the laser spectroscopic method in detail, present updated and improved values from theory and experiment, and discuss the results.

AB - Changes in the mean square nuclear charge radii along the lithium isotopic chain were determined using a combination of precise isotope shift measurements and theoretical atomic structure calculations. Nuclear charge radii of light elements are of high interest due to the appearance of the nuclear halo phenomenon in this region of the nuclear chart. During the past years we have developed a laser spectroscopic approach to determine the charge radii of lithium isotopes which combines high sensitivity, speed, and accuracy to measure the extremely small field shift of an 8-ms-lifetime isotope with production rates on the order of only 10 000 atoms/s. The method was applied to all bound isotopes of lithium including the two-neutron halo isotope Li11 at the on-line isotope separators at GSI, Darmstadt, Germany, and at TRIUMF, Vancouver, Canada. We describe the laser spectroscopic method in detail, present updated and improved values from theory and experiment, and discuss the results.

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JF - Physical Review A - Atomic, Molecular, and Optical Physics

IS - 1

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ER -

Isotope-shift measurements of stable and short-lived lithium isotopes for nuclear-charge-radii determination

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