Examining the nuclear mass surface of Rb and Sr isotopes in the A≈104 region via precision mass measurements

I Mukul; C Andreoiu; J  Bergmann; M  Brodeur; T Brunner; K A  Dietrich; T Dickel; I Dillmann; E Dunling; D Fusco; G Gwinner; C Izzo; A Jacobs; B Kootte; Y Lan; E  Leistenschneider; E M Lykiardopoulou; S F Paul; M. P. Reiter; J L Tracy Jr; J Dilling; A A Kwiatkowski

doi:10.1103/PhysRevC.103.044320

Examining the nuclear mass surface of Rb and Sr isotopes in the A≈104 region via precision mass measurements

I Mukul, C Andreoiu, J Bergmann, M Brodeur, T Brunner, K A Dietrich, T Dickel, I Dillmann, E Dunling, D Fusco, G Gwinner, C Izzo, A Jacobs, B Kootte, Y Lan, E Leistenschneider, E M Lykiardopoulou, S F Paul, M. P. Reiter, J L Tracy JrJ Dilling, A A Kwiatkowski

School of Physics and Astronomy

Research output: Contribution to journal › Article › peer-review

Abstract

Background: The neutron-rich A≈100, N≈62 mass region is important for both nuclear structure and nuclear astrophysics. The neutron-rich segment of this region has been widely studied to investigate shape coexistence and sudden nuclear deformation. However, the absence of experimental data of more neutron-rich nuclei poses a challenge to further structure studies. The derivatives of the mass surface, namely, the two-neutron separation energy and neutron pairing gap, are sensitive to nuclear deformation and shed light on the stability against deformation in this region. This region also lies along the astrophysical r-process path, and hence precise mass values provide experimental input for improving the accuracy of the r-process models and the elemental abundances.

Purpose: (a) Changes in deformation are searched for via the mass surface in the A=104 mass region at the N=66 mid-shell crossover. (b) The sensitivity of the astrophysical r-process abundances to the mass of Rb and Sr isotopic chains is studied.

Methods: Masses of radioactive Rb and Sr isotopes are precisely measured using a Multiple-Reflection Time-of-Flight Mass Separator (MR-TOF-MS) at the TITAN facility. These mass values are used to calculate two-neutron separation energies, two-neutron shell gaps and neutron pairing gaps for nuclear structure physics, and one-neutron separation energies for fractional abundances and astrophysical findings.

Results: We report the first mass measurements of 103Rb and 103–105Sr with uncertainties of less than 45 keV/c2. The uncertainties in the mass excess value for 102Rb and 102Sr have been reduced by a factor of 2 relative to a previous measurement. The deviations from the AME extrapolated mass values by more the 0.5 MeV have been found.

Conclusions: The metrics obtained from the derivatives of the mass surface demonstrate no existence of a subshell gap or onset of deformation in the N=66 region in Rb and Sr isotopes. The neutron pairing gaps studied in this work are lower than the predictions by several mass models. The abundances calculated using the waiting-point approximation for the r process are affected by these new masses in comparison with AME2016 mass values.

Original language	English
Article number	044320
Pages (from-to)	103
Number of pages	4
Journal	Physical Review C
Volume	103
Issue number	4
DOIs	https://doi.org/10.1103/PhysRevC.103.044320
Publication status	Published - 28 Apr 2021

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Mukul, I., Andreoiu, C., Bergmann, J., Brodeur, M., Brunner, T., Dietrich, K. A., Dickel, T., Dillmann, I., Dunling, E., Fusco, D., Gwinner, G., Izzo, C., Jacobs, A., Kootte, B., Lan, Y., Leistenschneider, E., Lykiardopoulou, E. M., Paul, S. F., Reiter, M. P., ... Kwiatkowski, A. A. (2021). Examining the nuclear mass surface of Rb and Sr isotopes in the A≈104 region via precision mass measurements. Physical Review C, 103(4), 103. Article 044320. https://doi.org/10.1103/PhysRevC.103.044320

@article{665e81466a55457aae69ed5a89cb1928,

title = "Examining the nuclear mass surface of Rb and Sr isotopes in the A≈104 region via precision mass measurements",

abstract = "Background: The neutron-rich A≈100, N≈62 mass region is important for both nuclear structure and nuclear astrophysics. The neutron-rich segment of this region has been widely studied to investigate shape coexistence and sudden nuclear deformation. However, the absence of experimental data of more neutron-rich nuclei poses a challenge to further structure studies. The derivatives of the mass surface, namely, the two-neutron separation energy and neutron pairing gap, are sensitive to nuclear deformation and shed light on the stability against deformation in this region. This region also lies along the astrophysical r-process path, and hence precise mass values provide experimental input for improving the accuracy of the r-process models and the elemental abundances.Purpose: (a) Changes in deformation are searched for via the mass surface in the A=104 mass region at the N=66 mid-shell crossover. (b) The sensitivity of the astrophysical r-process abundances to the mass of Rb and Sr isotopic chains is studied.Methods: Masses of radioactive Rb and Sr isotopes are precisely measured using a Multiple-Reflection Time-of-Flight Mass Separator (MR-TOF-MS) at the TITAN facility. These mass values are used to calculate two-neutron separation energies, two-neutron shell gaps and neutron pairing gaps for nuclear structure physics, and one-neutron separation energies for fractional abundances and astrophysical findings.Results: We report the first mass measurements of 103Rb and 103–105Sr with uncertainties of less than 45 keV/c2. The uncertainties in the mass excess value for 102Rb and 102Sr have been reduced by a factor of 2 relative to a previous measurement. The deviations from the AME extrapolated mass values by more the 0.5 MeV have been found.Conclusions: The metrics obtained from the derivatives of the mass surface demonstrate no existence of a subshell gap or onset of deformation in the N=66 region in Rb and Sr isotopes. The neutron pairing gaps studied in this work are lower than the predictions by several mass models. The abundances calculated using the waiting-point approximation for the r process are affected by these new masses in comparison with AME2016 mass values.",

author = "I Mukul and C Andreoiu and J Bergmann and M Brodeur and T Brunner and Dietrich, {K A} and T Dickel and I Dillmann and E Dunling and D Fusco and G Gwinner and C Izzo and A Jacobs and B Kootte and Y Lan and E Leistenschneider and Lykiardopoulou, {E M} and Paul, {S F} and Reiter, {M. P.} and {Tracy Jr}, {J L} and J Dilling and Kwiatkowski, {A A}",

year = "2021",

month = apr,

day = "28",

doi = "10.1103/PhysRevC.103.044320",

language = "English",

volume = "103",

pages = "103",

journal = "Physical Review C",

issn = "2469-9985",

publisher = "American Physical Society",

number = "4",

}

Mukul, I, Andreoiu, C, Bergmann, J, Brodeur, M, Brunner, T, Dietrich, KA, Dickel, T, Dillmann, I, Dunling, E, Fusco, D, Gwinner, G, Izzo, C, Jacobs, A, Kootte, B, Lan, Y, Leistenschneider, E, Lykiardopoulou, EM, Paul, SF, Reiter, MP, Tracy Jr, JL, Dilling, J & Kwiatkowski, AA 2021, 'Examining the nuclear mass surface of Rb and Sr isotopes in the A≈104 region via precision mass measurements', Physical Review C, vol. 103, no. 4, 044320, pp. 103. https://doi.org/10.1103/PhysRevC.103.044320

TY - JOUR

T1 - Examining the nuclear mass surface of Rb and Sr isotopes in the A≈104 region via precision mass measurements

AU - Mukul, I

AU - Andreoiu, C

AU - Bergmann, J

AU - Brodeur, M

AU - Brunner, T

AU - Dietrich, K A

AU - Dickel, T

AU - Dillmann, I

AU - Dunling, E

AU - Fusco, D

AU - Gwinner, G

AU - Izzo, C

AU - Jacobs, A

AU - Kootte, B

AU - Lan, Y

AU - Leistenschneider, E

AU - Lykiardopoulou, E M

AU - Paul, S F

AU - Reiter, M. P.

AU - Tracy Jr, J L

AU - Dilling, J

AU - Kwiatkowski, A A

PY - 2021/4/28

Y1 - 2021/4/28

N2 - Background: The neutron-rich A≈100, N≈62 mass region is important for both nuclear structure and nuclear astrophysics. The neutron-rich segment of this region has been widely studied to investigate shape coexistence and sudden nuclear deformation. However, the absence of experimental data of more neutron-rich nuclei poses a challenge to further structure studies. The derivatives of the mass surface, namely, the two-neutron separation energy and neutron pairing gap, are sensitive to nuclear deformation and shed light on the stability against deformation in this region. This region also lies along the astrophysical r-process path, and hence precise mass values provide experimental input for improving the accuracy of the r-process models and the elemental abundances.Purpose: (a) Changes in deformation are searched for via the mass surface in the A=104 mass region at the N=66 mid-shell crossover. (b) The sensitivity of the astrophysical r-process abundances to the mass of Rb and Sr isotopic chains is studied.Methods: Masses of radioactive Rb and Sr isotopes are precisely measured using a Multiple-Reflection Time-of-Flight Mass Separator (MR-TOF-MS) at the TITAN facility. These mass values are used to calculate two-neutron separation energies, two-neutron shell gaps and neutron pairing gaps for nuclear structure physics, and one-neutron separation energies for fractional abundances and astrophysical findings.Results: We report the first mass measurements of 103Rb and 103–105Sr with uncertainties of less than 45 keV/c2. The uncertainties in the mass excess value for 102Rb and 102Sr have been reduced by a factor of 2 relative to a previous measurement. The deviations from the AME extrapolated mass values by more the 0.5 MeV have been found.Conclusions: The metrics obtained from the derivatives of the mass surface demonstrate no existence of a subshell gap or onset of deformation in the N=66 region in Rb and Sr isotopes. The neutron pairing gaps studied in this work are lower than the predictions by several mass models. The abundances calculated using the waiting-point approximation for the r process are affected by these new masses in comparison with AME2016 mass values.

AB - Background: The neutron-rich A≈100, N≈62 mass region is important for both nuclear structure and nuclear astrophysics. The neutron-rich segment of this region has been widely studied to investigate shape coexistence and sudden nuclear deformation. However, the absence of experimental data of more neutron-rich nuclei poses a challenge to further structure studies. The derivatives of the mass surface, namely, the two-neutron separation energy and neutron pairing gap, are sensitive to nuclear deformation and shed light on the stability against deformation in this region. This region also lies along the astrophysical r-process path, and hence precise mass values provide experimental input for improving the accuracy of the r-process models and the elemental abundances.Purpose: (a) Changes in deformation are searched for via the mass surface in the A=104 mass region at the N=66 mid-shell crossover. (b) The sensitivity of the astrophysical r-process abundances to the mass of Rb and Sr isotopic chains is studied.Methods: Masses of radioactive Rb and Sr isotopes are precisely measured using a Multiple-Reflection Time-of-Flight Mass Separator (MR-TOF-MS) at the TITAN facility. These mass values are used to calculate two-neutron separation energies, two-neutron shell gaps and neutron pairing gaps for nuclear structure physics, and one-neutron separation energies for fractional abundances and astrophysical findings.Results: We report the first mass measurements of 103Rb and 103–105Sr with uncertainties of less than 45 keV/c2. The uncertainties in the mass excess value for 102Rb and 102Sr have been reduced by a factor of 2 relative to a previous measurement. The deviations from the AME extrapolated mass values by more the 0.5 MeV have been found.Conclusions: The metrics obtained from the derivatives of the mass surface demonstrate no existence of a subshell gap or onset of deformation in the N=66 region in Rb and Sr isotopes. The neutron pairing gaps studied in this work are lower than the predictions by several mass models. The abundances calculated using the waiting-point approximation for the r process are affected by these new masses in comparison with AME2016 mass values.

U2 - 10.1103/PhysRevC.103.044320

DO - 10.1103/PhysRevC.103.044320

M3 - Article

SN - 2469-9985

VL - 103

SP - 103

JO - Physical Review C

JF - Physical Review C

IS - 4

M1 - 044320

ER -

Examining the nuclear mass surface of Rb and Sr isotopes in the A≈104 region via precision mass measurements

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