J. P. Svenne scite author profile

Canton et al. Reply: In the preceding Comment, Fortune and Sherr (FS) agree with our prediction on the existence of three narrow odd-parity resonances in 15 F, finding them within the same excitation range and having the same spinparity and level ordering. Their argument, based upon a very different approach from ours, concerns some differences in the resonance centroids and widths. They conclude that the energies and widths of these narrow resonances might be considerably different from what we found.FS comment first on the energy centroids of the three narrow resonances. As the relevant question has been addressed in our Letter [1], we only remind readers that the energies of these narrow states are shifted higher from the results obtained by including the pure Coulomb effects to the mirror states in 15 C. The central term of the p-14 O nuclear potential required a shift of 0.8 MeV (with respect to the n-14 C potential) to find the appropriate centroid and width values of the 1 2

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Role of the Pauli Principle in Collective-Model Coupled-Channel Calculations

Canton

et al. 2005

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A multi-channel algebraic scattering theory, to find solutions of coupled-channel scattering problems with interactions determined by collective models, has been structured to ensure that the Pauli principle is not violated. By tracking the results in the zero coupling limit, a correct interpretation of the sub-threshold and resonant spectra of the compound system can be made. As an example, the neutron-12 C system is studied defining properties of 13 C to 10 MeV excitation. Accounting for the Pauli principle in collective coupled-channels models is crucial to the outcome. 25.40.Dn;25.40.Ny;28.20.Cz At energies above 25 MeV, by using optical potentials formed by full folding effective two-nucleon interactions with microscopic (nucleon based) descriptions of the target structure, the importance of treating the Pauli principle has been well established [1]. However, in the domain of low-energy nucleon scattering for which an explicit coupled-channels theory of scattering is essential, the significance of Pauli exclusion effects has not been well defined. Many coupled-channels codes are available, some of which perform phenomenological collective-model calculations searching on parameter values of the chosen function forms to find a best fit to experimental data. But while it has long been known that any such models violate the Pauli principle [2,3], quantification of that violation is lacking.To study the effects of the Pauli principle in a macroscopic (collective model) approach is not a trivial task. In a recent publication [4], the orthogonalizing pseudopotential (OPP) method [5,6] was generalized to treat this problem. That was a small though important part of the full theoretical framework of the multi-channel algebraic scattering (MCAS) theory of scattering [4]. Therein the OPP was used in finding the spectra, bound and resonance properties, of 13 C. However, implications of the role of the Pauli principle in collective model coupledchannel calculations arising from the use of the OPP was not discussed. Such is a purpose of this letter. Another is that the method could be pertinent for any study requiring coupled channel solutions of quantal systems involving fermions. As the example, we study the effects introduced by the Pauli principle in collective, geometrical-type, models for low-energy nucleon-nucleus processes that can be characterized from the spectrum of the compound nucleus. That spectrum includes the states that lie below the nucleon-nucleus threshold and in the continuum as revealed by the narrow and broad resonances that lie upon a smooth but energy dependent background of the elastic scattering cross section. This can be done in a systematic and self-consistent way since the MCAS approach facilitates such a determination of the sub-threshold bound states and resonances of the compound nucleus. This theory, with which one solves the coupled-channel Lippmann-Schwinger (LS) equations for the nucleon-nucleus system considered, is built upon sturmian expansions of an interaction matrix of potent...

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Collective-coupling analysis of spectra of mass-7 isobars:He7,Li7
Canton
¹
,
Pisent
²
,
Amos
³

et al. 2006
Phys. Rev. C
28
1
95
2
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A nucleon-nucleus interaction model has been applied to ascertain the underlying character of the negative-parity spectra of four isobars of mass seven, from neutron-to proton-emitter driplines. With one and the same nuclear potential defined by a simple coupled-channel model, a multichannel algebraic scattering approach (MCAS) has been used to determine the bound and resonant spectra of the four nuclides, of which 7 He and 7 B are particle unstable. Incorporation of Pauli blocking in the model enables a description of all known spin-parity states of the mass-7 isobars. We have also obtained spectra of similar quality by using a large space no-core shell model. Additionally, we have studied 7 Li and 7 Be using a dicluster model. We have found a dicluster-model potential that can reproduce the lowest four states of the two nuclei, as well as the relevant low-energy elastic scattering cross sections. But, with this model, the rest of the energy spectra cannot be obtained.

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J. P. Svenne

Cantonet al.Reply:

Role of the Pauli Principle in Collective-Model Coupled-Channel Calculations

Collective-coupling analysis of spectra of mass-7 isobars:He7,Li7
Canton
¹
,
Pisent
²
,
Amos
³

et al. 2006
Phys. Rev. C
28
1
95
2
View full text Add to dashboard Cite

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J. P. Svenne

Cantonet al.Reply:

Role of the Pauli Principle in Collective-Model Coupled-Channel Calculations

Collective-coupling analysis of spectra of mass-7 isobars:He7,Li7Canton1, Pisent2, Amos3 et al. 2006Phys. Rev. C281952View full textAdd to dashboardCite

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Collective-coupling analysis of spectra of mass-7 isobars:He7,Li7
Canton
¹
,
Pisent
²
,
Amos
³

et al. 2006
Phys. Rev. C
28
1
95
2
View full text Add to dashboard Cite