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 transition strength in stable Ni isotopes

Evitts, L. J.; Garnsworthy, A. B.; Kibédi, T.; Smallcombe, J.; Reed, M. W.; Stuchbery, A.E.; Lane, G. J.; Akber, A.; Alshahrani, B.; Vries, M. de; Gerathy, M. S. M.; Holt, J. D.; Lee, Boon Quan; McCormick, B. P.; Mitchell, A. J.; Moukaddam, M.; Mukhopadhyay, S.; Palalani, N.; Palazzo, T.; Peters, E. E.; Ramirez, A. P. D.; Tornyi, T.; Yates, S. W.

doi:10.1103/physrevc.99.024306

Cited by 11 publications

(24 citation statements)

References 44 publications

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“…Multiple applications of the EMλ/ Hamiltonians in support of spectroscopy experiments have been published in recent years (see, e.g., [197,[205][206][207][208]…”

Section: And Section 323)mentioning

confidence: 99%

A Guided Tour of ab initio Nuclear Many-Body Theory

2020

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Over the last decade, new developments in Similarity Renormalization Group techniques and nuclear many-body methods have dramatically increased the capabilities of ab initio nuclear structure and reaction theory. Ground and excited-state properties can be computed up to the tin region, and from the proton to the presumptive neutron drip lines, providing unprecedented opportunities to confront two-plus three-nucleon interactions from chiral Effective Field Theory with experimental data. In this contribution, I will give a broad survey of the current status of nuclear many-body approaches, and I will use selected results to discuss both achievements and open issues that need to be addressed in the coming decade.

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“…Multiple applications of the EMλ/ Hamiltonians in support of spectroscopy experiments have been published in recent years (see, e.g., [197,[205][206][207][208]…”

Section: And Section 323)mentioning

confidence: 99%

A Guided Tour of ab initio Nuclear Many-Body Theory

2020

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“…Unfortunately, there is a large uncertainty on the reported E0 strengths in this work due to the uncertainty in the state lifetimes, and the transition branching and mixing ratios. The unprecedented strength in this region (Ca -Ni) [7,8,14,15] is still not understood, and further measurements of both the E0 transition strengths, along with other spectroscopic quantities like mixing ratios, are needed to reduce the uncertainty on the E0 transition strengths and to understand the structure of these nuclei.…”

Section: Resultsmentioning

confidence: 99%

“…Large E0 strengths have been recently observed in the Ni isotopes (Z = 28) [7,8], but it is unknown if shape coexistence is present in the N = 28 isotones between doubly magic 48 Ca and 56 Ni. Theoretically, shape coexistence has been predicted in the N = 28 isotones [9], resulting from the excitation of a neutron pair across the N = 28 closed neutron shell from the f 7/2 shell into the f p shell.…”

Section: Introductionmentioning

confidence: 99%

“…In order to resolve these limitations, an experimental campaign investigating these properties of 52 Cr is planned to take place at the University of Kentucky Accelerator Laboratory (UKAL). The inelastic neutron scattering reaction, (n, n ), has been successfully used to measure nuclear lifetimes via the Doppler-shift attenuation method (DSAM) and mixing ratios via angular distributions in the Ni isotopes, which were needed for accurate E0 strength determination [7,8,28].…”

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Evidence for shape coexistence in ⁵²Cr through conversion-electron and pair-conversion spectroscopy

et al. 2020

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Electric monopole (E0) transitions are a highly sensitive probe of the charge distribution of an atomic nucleus. A large E0 transition strength (ρ2(E0)) is a clear indicator of nuclear shape coexistence. In the region between doubly magic 40Ca and 56Ni, E0 transitions have never been observed in the Ti or Cr isotopes, nor in the heavier iron isotopes (56,58Fe). We have performed the first measurements of the E0 transitions in 52Cr via conversion-electron and pair-conversion spectroscopy using the Super-e spectrometer at the Australian National University Heavy Ion Accelerator Facility. We present the first spectra obtained for 52Cr, including the first observation of the E0 transition from the first-excited 0+ state in 52Cr, in both electron-positron pairs and conversion-electron spectroscopy. The preliminary values for the E0 strength in the 1531keV 2+ → 2+ transition in 52Cr is ρ2(E0) × 103 = 470(190), and for the 1728-keV 23+ → 21+ transition, it is ρ2(E0) 103 = 1800(1200). The large E0 strengths observed are consistent with shape coexistence in this region. However, despite the relatively precise observation of the conversion-electron and electron-positron pair intensities, the E0 strengths have large uncertainties. More precise determinations of relevant spectroscopic quantities, such as the state lifetimes and transition mixing ratios for mixed M1 + E2 transitions, are needed to determine the E0 strength more precisely.

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“…More recently, pair spectroscopy has been used to study E0 transitions in relatively low-Z nuclei. Examples are 0 + → 0 + transitions in the N = Z nuclei 24 Mg and 40 Ca, and a systematic study of E0 transition strengths near N = 28 and Z = 28 that is finding that strong E0 transitions occur only in the semimagic isotopes [39][40][41].…”

Section: Line 6: Super-e: Conversion Electrons and Pair Spectroscopymentioning

confidence: 99%

The Heavy Ion Accelerator Facility: Research Achievements and Aspirations

Stuchbery

2020

EPJ Web Conf.

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An overview of Australia’s Heavy Ion Accelerator Facility (HIAF) is presented, including a survey of the accelerator infrastructure and its capabilities, as well as the beam-line instrumentation. Some recent research achievements are highlighted. Accelerator upgrades and instrumentation developments in progress are described, along with some aspirations for the longer-term development of the Facility and its associated research programs.

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E0 transition strength in stable Ni isotopes

Cited by 11 publications

References 44 publications

A Guided Tour of ab initio Nuclear Many-Body Theory

A Guided Tour of ab initio Nuclear Many-Body Theory

Evidence for shape coexistence in ⁵²Cr through conversion-electron and pair-conversion spectroscopy

The Heavy Ion Accelerator Facility: Research Achievements and Aspirations

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E0 transition strength in stable Ni isotopes

Cited by 11 publications

References 44 publications

A Guided Tour of ab initio Nuclear Many-Body Theory

A Guided Tour of ab initio Nuclear Many-Body Theory

Evidence for shape coexistence in 52Cr through conversion-electron and pair-conversion spectroscopy

The Heavy Ion Accelerator Facility: Research Achievements and Aspirations

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Product

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Evidence for shape coexistence in ⁵²Cr through conversion-electron and pair-conversion spectroscopy