Asymmetry Dependence of Proton Correlations

Charity, R. J.; Sobotka, L. G.; Dickhoff, W. H.

doi:10.1103/physrevlett.97.162503

Cited by 77 publications

(137 citation statements)

References 33 publications

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“…The USDB shell-model calculations (in agreement with the mirror nucleus) predict a 27 P first excited state with spin and parity 3/2 + at 990 keV, just above the proton separation energy of 861 (27) keV [43]. However, in qualitative agreement with the high 3/2 + excitation energy reported in Ref.…”

Section: A Removal Of Weakly Bound Protonssupporting

confidence: 65%

“…The USDB shell model predicts these states to be almost degenerate. In the γ -ray spectrum, taken in coincidence with 27 S, a weak low-energy transition cannot be excluded but its identification is obscured by background and hampered by low statistics. As outlined below, this is consistent with the level ordering proposed by the shell model.…”

Section: B Removal Of Strongly Bound Neutronsmentioning

confidence: 99%

“…It was suggested that this may indeed reflect enhanced correlation effects, absent from the underlying effective-interaction theory, linked to the large asymmetry in the Fermi energies of the neutron and proton states in nuclei near the drip lines [15]. Recent theoretical work, involving a dispersive optical model analysis of nucleon elastic scattering data [27], also indicates that nucleons of the deficient species will become more strongly correlated with increasing asymmetry, whereas the opposite holds for the nucleons of the excess species, in qualitative agreement with the observations reported above [15].…”

Section: Introductionmentioning

confidence: 99%

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Reduction of spectroscopic strength: Weakly-bound and strongly-bound single-particle states studied using one-nucleon knockout reactions

et al. 2008

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Both one-proton and one-neutron knockout reactions were performed with fast beams of two asymmetric, neutron-deficient rare isotopes produced by projectile fragmentation. The reactions are used to probe the nucleon spectroscopic strengths at both the weakly and strongly bound nucleon Fermi surfaces. The one-proton knockout reactions 9 Be( 28 S, 27 P)X and 9 Be( 24 Si, 23 Al)X probe the weakly bound valence proton states and the one-neutron knockout reactions and 9 Be( 28 S, 27 S)X and 9 Be( 24 Si, 23 Si)X the strongly bound neutron states in the two systems. The spectroscopic strengths are extracted from the measured cross sections by comparisons with an eikonal reaction theory. The reduction of the experimentally deduced spectroscopic strengths, relative to the predictions of shell-model calculations, is of order 0.8-0.9 in the removal of weakly bound protons and 0.3-0.4 in the knockout of the strongly bound neutrons. These results support previous studies at the extremes of nuclear binding and provide further evidence that in asymmetric nuclear systems the nucleons of the deficient species, at the more-bound Fermi surface are more strongly correlated than those of the more weakly bound excess species.

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Section: A Removal Of Weakly Bound Protonssupporting

confidence: 65%

Section: B Removal Of Strongly Bound Neutronsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Reduction of spectroscopic strength: Weakly-bound and strongly-bound single-particle states studied using one-nucleon knockout reactions

et al. 2008

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“…This idea was implemented in the dispersive optical model (DOM) by Mahaux and Sartor [5]. By employing dispersion relations, the method provides a critical link between the physics above and below the Fermi energy with both sides being influenced by the absorptive potentials on the other side.The DOM provides an ideal strategy to predict properties for exotic nuclei by utilizing extrapolations of these potentials towards the respective drip lines [6,7]. The main stumbling block so far has been the need to utilize the approximate expressions for the properties of nucleons below the Fermi energy that were developed by Mahaux and Sartor [5] to correct for the normalizationdistorting energy dependence of the Hartree-Fock (HF) potential.…”

mentioning

confidence: 99%

“…The DOM provides an ideal strategy to predict properties for exotic nuclei by utilizing extrapolations of these potentials towards the respective drip lines [6,7]. The main stumbling block so far has been the need to utilize the approximate expressions for the properties of nucleons below the Fermi energy that were developed by Mahaux and Sartor [5] to correct for the normalizationdistorting energy dependence of the Hartree-Fock (HF) potential.…”

mentioning

confidence: 99%

Forging the Link between Nuclear Reactions and Nuclear Structure

et al. 2014

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A comprehensive description of all single-particle properties associated with the nucleus 40 Ca is generated by employing a nonlocal dispersive optical potential capable of simultaneously reproducing all relevant data above and below the Fermi energy. The introduction of nonlocality in the absorptive potentials yields equivalent elastic differential cross sections as compared to local versions but changes the absorption profile as a function of angular momentum suggesting important consequences for the analysis of nuclear reactions. Below the Fermi energy, nonlocality is essential to allow for an accurate representation of particle number and the nuclear charge density. Spectral properties implied by (e, e ′ p) and (p, 2p) reactions are correctly incorporated, including the energy distribution of about 10% high-momentum nucleons, as experimentally determined by data from Jefferson Lab. These high-momentum nucleons provide a substantial contribution to the energy of the ground state, indicating a residual attractive contribution from higher-body interactions for 40 Ca of about 0.64 MeV/A.PACS numbers: 21.10. Pc,24.10.Ht,11.55.Fv The properties of a nucleon that is strongly influenced by the presence of other nucleons have traditionally been studied in separate energy domains. Positive energy nucleons are described by fitted optical potentials mostly in local form [1,2]. Bound nucleons have been analyzed in static potentials that lead to an independent-particle model modified by the interaction between valence nucleons as in traditional shell-model calculations [3,4]. The link between nuclear reactions and nuclear structure is provided by considering these potentials as representing different energy domains of one underlying nucleon self-energy. This idea was implemented in the dispersive optical model (DOM) by Mahaux and Sartor [5]. By employing dispersion relations, the method provides a critical link between the physics above and below the Fermi energy with both sides being influenced by the absorptive potentials on the other side.The DOM provides an ideal strategy to predict properties for exotic nuclei by utilizing extrapolations of these potentials towards the respective drip lines [6,7]. The main stumbling block so far has been the need to utilize the approximate expressions for the properties of nucleons below the Fermi energy that were developed by Mahaux and Sartor [5] to correct for the normalizationdistorting energy dependence of the Hartree-Fock (HF) potential. By restoring the proper treatment of nonlocality in the HF contribution, it was possible to overcome this problem [8] although the local treatment of the absorptive potentials yielded a poor description of the nuclear charge density and particle number.In the present work we have for the first time treated the nonlocality of these potentials for the nucleus 40 Ca with the aim to include all available data below the Fermi energy that can be linked to the nucleon single-particle propagator [9] while maintaining a correct description of the el...

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Nuclear Reactions

Sobotka¹,

Viola²

2011

Handbook of Nuclear Chemistry

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Asymmetry Dependence of Proton Correlations

Cited by 77 publications

References 33 publications

Reduction of spectroscopic strength: Weakly-bound and strongly-bound single-particle states studied using one-nucleon knockout reactions

Reduction of spectroscopic strength: Weakly-bound and strongly-bound single-particle states studied using one-nucleon knockout reactions

Forging the Link between Nuclear Reactions and Nuclear Structure

Nuclear Reactions

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