1981
DOI: 10.1016/0375-9474(81)90123-8
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Spectroscopic amplitudes for complex cluster systems

Abstract: By expanding the Bargmann-Segal integral transform of norm and overlap kernels in appropriately SU(3) coupled Bargmann space functions, the calculation of norm and overlap matrix elements in a cluster model basis is reduced to purely algebraic techniques involving the algebra of SU(3) recoupling transformations. This technique has been further developed to make calculations possible for systems of two heavy fragments other than closed-shell nuclei. In one application of the method, analytic expressions are giv… Show more

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Cited by 44 publications
(19 citation statements)
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“…Another important feature is that once the overlaps are calculated in labframe coordinates, the translationally-invariant overlaps can be straightforwardly calculated using an U(A)× U(3) approach, which is especially suitable for the SU(3)-coupled wave functions [207]. Applications of the model to the intermediate-mass region typically employ leading SU(3) configurations in the cluster wave functions and Gaussian-like interactions, and have successfully calculated α and 8 Be cluster amplitudes, spectroscopic amplitudes for heavy-fragment clusters, and sub-Coulomb 12 C+ 12 C resonances [209][210][211]. Sp(3, R)-scheme RGM.…”
Section: Cluster Modelmentioning
confidence: 99%
“…Another important feature is that once the overlaps are calculated in labframe coordinates, the translationally-invariant overlaps can be straightforwardly calculated using an U(A)× U(3) approach, which is especially suitable for the SU(3)-coupled wave functions [207]. Applications of the model to the intermediate-mass region typically employ leading SU(3) configurations in the cluster wave functions and Gaussian-like interactions, and have successfully calculated α and 8 Be cluster amplitudes, spectroscopic amplitudes for heavy-fragment clusters, and sub-Coulomb 12 C+ 12 C resonances [209][210][211]. Sp(3, R)-scheme RGM.…”
Section: Cluster Modelmentioning
confidence: 99%
“…The contracted symplectic model (of U b (6)⊗U s (3)), is a collective model, obtained as the large N limit of the multi major-shell symplectic model [37,38]. The fully microscopic [39,40] as well as the semimicroscopic algebraic cluster model [25] are equiped with a U C (3)⊗U R (3) basis. All these models are based on the L-S-coupled scheme, and the spin-isospin sector is described by Wigner's SU S T (4) symmetry.…”
Section: Classification Of Nuclear Statesmentioning
confidence: 99%
“…But, since the clusters are identical in our case, these quantum numbers characterizing the internal cluster configuration of the C+ C system can not be combined with any excitation of the relative motion. It can be shown [15] that combinations with only n + A~+ pc =even are allowed here, i.e. , (Ac, pc) = (0,8), (2,4), and (4,0) can be combined with even values of n (and positive parity), while (Ac, pc) = (1,6) and (3,2) can occur only if n"( ad nconsequently the parity) is odd.…”
Section: A the I C+ C Model Spacementioning
confidence: 99%
“…The model space obtained this way turned out to be larger than that derived from the solution of the eigenvalue problem of the norm kernel [12,15]. In particular, we had some extra multiplicities for each value of n we studied (i.e.…”
Section: A the I C+ C Model Spacementioning
confidence: 99%
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