D. Atanasov scite author profile

This is an exciting time for the study of r-process nucleosynthesis. Recently, a neutron star merger GW170817 was observed in extraordinary detail with gravitational waves and electromagnetic radiation from radio to γ rays. The very red color of the associated kilonova suggests that neutron star mergers are an important r-process site. Astrophysical simulations of neutron star mergers and core collapse supernovae are making rapid progress. Detection of both, electron neutrinos and antineutrinos from the next galactic supernova will constrain the composition of neutrino-driven winds and provide unique nucleosynthesis information. Finally FRIB and other rare-isotope beam facilities will soon have dramatic new capabilities to synthesize many neutron-rich nuclei that are involved in the r-process. The new capabilities can significantly improve our understanding of the r-process and likely resolve one of the main outstanding problems in classical nuclear astrophysics.However, to make best use of the new experimental capabilities and to fully interpret the results, a great deal of infrastructure is needed in many related areas of astrophysics, astronomy, and nuclear theory. We will place these experiments in context by discussing astrophysical simulations and observations of r-process sites, observations of stellar abundances, galactic chemical evolution, and nuclear theory for the structure and reactions of very neutron-rich nuclei. This review paper was initiated at a three-week International Collaborations in Nuclear Theory program in June 2016 where we explored promising r-process experiments and discussed their likely impact, and their astrophysical, astronomical, and nuclear theory context.

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ISOLTRAP's multi-reflection time-of-flight mass separator/spectrometer

Wolf¹,

Wienholtz²,

Atanasov³

et al. 2013

International Journal of Mass Spectrometry

161

112

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Characterization of the shape-staggering effect in mercury nuclei

et al. 2018

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Atomic nuclei exhibit single-particle and collective degrees of freedom, making them susceptible to variations in size and shape when adding or removing nucleons. The rare cases where dramatic changes in shape occur with the removal of only a single nucleon are key for pinpointing the components of the nuclear interaction driving nuclear deformation. Laser spectroscopy probes the nuclear charge distribution, revealing attometer-scale variations and highlighting sensitivity to the proton (Z) and neutron (N) configurations of the nucleus. The lead isotopes, which possess a closed proton shell (Z = 82), are spherical and steadily shrink with decreasing N. A surprisingly different story was observed for their close neighbours, the mercury isotopes (Z = 80) almost half a century ago 1, 2 : Whilst the even-mass isotopes follow the trend seen for lead, the odd-mass isotopes 181,183,185 Hg exhibit a striking increase in charge radius. This dramatic 'shape staggering' between evenand odd-mass isotopes remains a unique feature of the nuclear chart. Here we present the extension of laser spectroscopy results that reach 177 Hg. An unprecedented combination of state-of-theart techniques including resonance laser ionization, nuclear spectroscopy and mass spectrometry, has established 181 Hg as the shape-staggering endpoint. Accompanying this experimental tour de force, recent computational advances incorporating the largest valence space ever used have been exploited to provide Monte-Carlo Shell Model calculations, in remarkable agreement with the experimental observations. Thus, microscopic insight into the subtle interplay of nuclear interactions that give rise to this phenomenon has been obtained, identifying the shape-driving orbitals. Although shape staggering in the mercury isotopes is a unique and localized feature in the nuclear chart, the underlying mechanism that has now been uncovered nicely describes the duality of single-particle and collective degrees of freedom in atomic nuclei.

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Probing theN=32Shell Closure below the Magic Proton NumberZ=20: Mass Measurements of the Exotic Isotopes<

et al. 2015

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The recently confirmed neutron-shell closure at N=32 has been investigated for the first time below the magic proton number Z=20 with mass measurements of the exotic isotopes (52,53)K, the latter being the shortest-lived nuclide investigated at the online mass spectrometer ISOLTRAP. The resulting two-neutron separation energies reveal a 3 MeV shell gap at N=32, slightly lower than for 52Ca, highlighting the doubly magic nature of this nuclide. Skyrme-Hartree-Fock-Bogoliubov and ab initio Gorkov-Green function calculations are challenged by the new measurements but reproduce qualitatively the observed shell effect.

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Storage ring at HIE-ISOLDE

Grieser

Litvinov

Raabe

et al. 2012

Eur. Phys. J. Spec. Top.

111

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We propose to install a storage ring at an ISOL-type radioactive beam facility for the first time. Specifically, we intend to install the heavy-ion, low-energy ring TSR at the HIE-ISOLDE facility in CERN, Geneva. Such a facility will provide a capability for experiments with stored secondary beams that is unique in the world. The envisaged physics programme is rich and varied, spanning from investigations of nuclear groundstate properties and reaction studies of astrophysical relevance, to investigations with highly-charged ions and pure isomeric beams. The TSR can also be used to remove isobaric contaminants from stored ion beams and for systematic studies within the neutrino beam programme. In addition to experiments performed using beams recirculating within the ring, cooled beams can also be extracted and exploited by external spectrometers for high-precision measurements. The existing TSR, which is presently in operation at the Max-Planck Institute for Nuclear Physics in Heidelberg, is well-suited and can be employed for this purpose. The physics cases, technical details of the existing ring facility and of the beam requirements at HIE-ISOLDE, together with the cost, time and manpower estimates for the transfer, installation and commissioning of the TSR at ISOLDE are discussed in the present technical design report.

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Binding Energy of Cu79 : Probing the Structure of the Doubly Magic Ni
Welker
¹
,
Althubiti
²
,
Atanasov
³

et al. 2017
Phys. Rev. Lett.
78
6
59
1
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The masses of the neutron-rich copper isotopes ^{75-79}Cu are determined using the precision mass spectrometer ISOLTRAP at the CERN-ISOLDE facility. The trend from the new data differs significantly from that of previous results, offering a first accurate view of the mass surface adjacent to the Z=28, N=50 nuclide ^{78}Ni and supporting a doubly magic character. The new masses compare very well with large-scale shell-model calculations that predict shape coexistence in a doubly magic ^{78}Ni and a new island of inversion for Z<28. A coherent picture of this important exotic region begins to emerge where excitations across Z=28 and N=50 form a delicate equilibrium with a spherical mean field.

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Precision Mass Measurements of Cr58–63 : Nuclear Collectivity Towards the N=40 Island

et al. 2018

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The neutron-rich isotopes 58−63 Cr were produced for the first time at the ISOLDE facility and their masses were measured with the ISOLTRAP spectrometer. The new values are up to 300 times more precise than those in the literature and indicate significantly different nuclear structure from the new mass-surface trend. A gradual onset of deformation is found in this proton and neutron mid-shell region, which is a gateway to the second island of inversion around N =40. In addition to comparisons with density-functional theory and large-scale shell-model calculations, we present predictions from the valence-space formulation of the ab initio in-medium similarity renormalization group, the first such results for open-shell chromium isotopes. PACS numbers: 82.80.Qx, 82.80.Rt, 21.10.Dr, 21.60.CsOver the last few decades, the stability of proton and neutron "magic" numbers has been a major focus of experimental nuclear physics. Early momentum came from the vanishing of the N =20 shell closure near 32 Mg in mass measurements [1] from which arose the idea of the "island of inversion".Extensive effort has followed to examine the classical signatures for magicity in exotic nuclei (e.g empirical shell gap or the energy of the first excited 2 + 1 state). More than three decades later, the robustness of all major shell closures has been assessed [2]. Along the way,

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Recent exploits of the ISOLTRAP mass spectrometer

Kreim

Atanasov

Beck

et al. 2013

Nuclear Instruments and Methods in Physics Research Section B:

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D. Atanasov

r-process nucleosynthesis: connecting rare-isotope beam facilities with the cosmos

ISOLTRAP's multi-reflection time-of-flight mass separator/spectrometer

Characterization of the shape-staggering effect in mercury nuclei

Probing theN=32Shell Closure below the Magic Proton NumberZ=20: Mass Measurements of the Exotic Isotopes<

Storage ring at HIE-ISOLDE

Binding Energy of Cu79 : Probing the Structure of the Doubly Magic Ni
Welker
¹
,
Althubiti
²
,
Atanasov
³

et al. 2017
Phys. Rev. Lett.
78
6
59
1
View full text Add to dashboard Cite

Precision Mass Measurements of Cr58–63 : Nuclear Collectivity Towards the N=40 Island

Recent exploits of the ISOLTRAP mass spectrometer

Contact Info

Product

Resources

About

D. Atanasov

r-process nucleosynthesis: connecting rare-isotope beam facilities with the cosmos

ISOLTRAP's multi-reflection time-of-flight mass separator/spectrometer

Characterization of the shape-staggering effect in mercury nuclei

Probing theN=32Shell Closure below the Magic Proton NumberZ=20: Mass Measurements of the Exotic Isotopes<

Storage ring at HIE-ISOLDE

Binding Energy of Cu79 : Probing the Structure of the Doubly Magic NiWelker1, Althubiti2, Atanasov3 et al. 2017Phys. Rev. Lett.786591View full textAdd to dashboardCite

Precision Mass Measurements of Cr58–63 : Nuclear Collectivity Towards the N=40 Island

Recent exploits of the ISOLTRAP mass spectrometer

Contact Info

Product

Resources

About

Binding Energy of Cu79 : Probing the Structure of the Doubly Magic Ni
Welker
¹
,
Althubiti
²
,
Atanasov
³

et al. 2017
Phys. Rev. Lett.
78
6
59
1
View full text Add to dashboard Cite