Proton superfluidity and charge radii in proton-rich calcium isotopes

Miller, A.; Minamisono, K.; Klose, A.; Garand, D.; Kujawa, C.; Lantis, Jeremy; Liu, Y.; Maaß, B.; Mantica, P. F.; Nazarewicz, W.; Nörtershäuser, W.; Pineda, Skyy; Reinhard, P.‐G.; Rossi, D.; Sommer, Felix; Sumithrarachchi, C.; Teigelhöfer, A.; Watkins, J.

doi:10.1038/s41567-019-0416-9

Cited by 134 publications

(111 citation statements)

References 45 publications

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“…[25]. The resulting model was found not only to reproduce the charge radii in the calcium isotopes but also to provide an excellent prediction for the iron radii at the N ¼ 28 shell closure [41], the very light calcium isotopes down to 36 Ca [42] and, remarkably, also for the much heavier Cd isotopes from 100 Cd to 130 Cd [28]. Motivated by the recent experimental and theoretical developments, we present here new data on charge radii for the even-even 108−134 Sn isotopes based on high-precision laser spectroscopic measurements, crossing for the first time the doubly magic N ¼ 82 shell closure in the tin isotopic chain.…”

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confidence: 89%

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Laser Spectroscopy of Neutron-Rich Tin Isotopes: A Discontinuity in Charge Radii across the N=82 Shell Closure

Gorges¹,

Rodríguez²,

Balabanski³

et al. 2019

Phys. Rev. Lett.

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109

117

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confidence: 89%

“…Theoretical analysis.-To understand the experimental findings, we employed nuclear DFT [50] at a spherical Hartree-Fock-Bogoliubov (HFB) level as in Ref. [42]. Calculations were carried out using two different energy functionals.…”

mentioning

confidence: 99%

Laser Spectroscopy of Neutron-Rich Tin Isotopes: A Discontinuity in Charge Radii across the N=82 Shell Closure

Gorges¹,

Rodríguez²,

Balabanski³

et al. 2019

Phys. Rev. Lett.

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109

117

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“…Measurements of the corresponding frequencies, typically of the order of MHz, allow changes in the root-mean-squared (rms) nuclear charge radii to be extracted [5,6]. Extending these measurements for isotopes away from stability is of marked and growing interest for low-energy nuclear physics, as the data on the nuclear size are essential for our understanding of the nuclear many-body problem [5,[7][8][9][10]. In recent years, the interest in precision isotope shift measurements has increased significantly.…”

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confidence: 99%

Beyond the charge radius: The information content of the fourth radial moment

2020

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Measurements of atomic transitions in different isotopes offer key information on the nuclear charge radius. The anticipated high-precision experimental techniques, augmented by atomic calculations, will soon enable extraction of the higher-order radial moments of the charge density distribution. To assess the value of such measurements for nuclear structure research, we study the information content of the fourth radial moment r 4 by means of nuclear density functional theory and a multiple correlation analysis. We show that r 4 can be directly related to the surface thickness of nuclear density, a fundamental property of the atomic nucleus that is difficult to obtain for radioactive systems. Precise knowledge of these radial moments is essential to establish reliable constraints on the existence of new forces from precision isotope shift measurements.

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“…Recently, unexpectedly large charge radii were observed in neutron-rich Ca isotopes beyond N = 28 [7]. This sudden growth in charge radii from 48 Ca (N = 28) to 52 Ca represents a challenging problem; it has not been quan-titatively explained by any theoretical calculations other than the Hartree-Fock-Bogolyubov calculation with the Fayans energy density functional [8]. This anomalous phenomenon observed in Ca isotopes is stimulating further studies of nuclear charge radii in a wide mass region [8][9][10][11][12].In contrast, information on the evolution of the size of the neutron density distribution has not been obtained across N = 28.…”

mentioning

confidence: 99%

“…This sudden growth in charge radii from 48 Ca (N = 28) to 52 Ca represents a challenging problem; it has not been quan-titatively explained by any theoretical calculations other than the Hartree-Fock-Bogolyubov calculation with the Fayans energy density functional [8]. This anomalous phenomenon observed in Ca isotopes is stimulating further studies of nuclear charge radii in a wide mass region [8][9][10][11][12].In contrast, information on the evolution of the size of the neutron density distribution has not been obtained across N = 28. For example, nucleon density distributions ρ m (r) or point-neutron density distributions ρ n (r) for Ca isotopes have been deduced only for stable nuclei, 40,42,44,48 Ca, through the hadron elastic scattering [13][14][15][16][17][18][19][20][21][22][23].The experimental data for root-mean-square (RMS) radii of ρ m (r) or ρ n (r) for Ca isotopes beyond N = 28…”

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confidence: 99%

Swelling of Doubly Magic Ca48 Core in Ca Isotopes beyond N=28

Tanaka¹,

Takechi²,

Homma³

et al. 2020

Phys. Rev. Lett.

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Interaction cross sections for 42-51 Ca on a carbon target at 280 MeV/nucleon have been measured for the first time. The neutron number dependence of derived root-mean-square matter radii shows a significant increase beyond the neutron magic number N = 28. Furthermore, this enhancement of matter radii is much larger than that of the previously measured charge radii, indicating a novel growth in neutron skin thickness. A simple examination based on the Fermi-type distribution, and the Mean-Field calculations point out that this anomalous enhancement of the nuclear size beyond N = 28 results from an enlargement of the core by a sudden increase in the surface diffuseness of the neutron density distribution, which implies the swelling of the bare 48 Ca core in Ca isotopes beyond N = 28. PACS numbers: 25.60.Dz Systematic studies of nuclear radii along the isotopic chain have so far elucidated changes in the nuclear structure such as the emergence of a halo as well as the development of neutron skin and nuclear deformation [1][2][3][4][5]. Nuclear charge radii, which represent charge spreads in these nuclei, also give complemental information on the size of the nucleus. It has been revealed that the trend of charge radii along the isotopic chain shows a sudden increase, which is often called a "kink," just after the magic number [6]. In particular, the neutron magic number N = 28 has received considerable attention. Recently, unexpectedly large charge radii were observed in neutron-rich Ca isotopes beyond N = 28 [7]. This sudden growth in charge radii from 48 Ca (N = 28) to 52 Ca represents a challenging problem; it has not been quan-titatively explained by any theoretical calculations other than the Hartree-Fock-Bogolyubov calculation with the Fayans energy density functional [8]. This anomalous phenomenon observed in Ca isotopes is stimulating further studies of nuclear charge radii in a wide mass region [8][9][10][11][12].In contrast, information on the evolution of the size of the neutron density distribution has not been obtained across N = 28. For example, nucleon density distributions ρ m (r) or point-neutron density distributions ρ n (r) for Ca isotopes have been deduced only for stable nuclei, 40,42,44,48 Ca, through the hadron elastic scattering [13][14][15][16][17][18][19][20][21][22][23].The experimental data for root-mean-square (RMS) radii of ρ m (r) or ρ n (r) for Ca isotopes beyond N = 28

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Proton superfluidity and charge radii in proton-rich calcium isotopes

Cited by 134 publications

References 45 publications

Laser Spectroscopy of Neutron-Rich Tin Isotopes: A Discontinuity in Charge Radii across the N=82 Shell Closure

Laser Spectroscopy of Neutron-Rich Tin Isotopes: A Discontinuity in Charge Radii across the N=82 Shell Closure

Beyond the charge radius: The information content of the fourth radial moment

Swelling of Doubly Magic Ca48 Core in Ca Isotopes beyond N=28

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