A computationally tractable version of the collective model

Rowe, D.J.

doi:10.1016/j.nuclphysa.2004.02.018

Cited by 102 publications

(117 citation statements)

References 35 publications

Supporting

Mentioning

109

Contrasting

Order By: Relevance

“…[19]. The low-energy level spectrum of the Hamiltonian (123), calculated with a large value of α [16], is shown in Fig. 8.…”

Section: Cosmentioning

confidence: 99%

“…It turns out that, for many purposes, other matrix elements are needed and are also needed for higher-dimensional spaces. For example, the nuclear collective model is defined on a five-dimensional space [15,16,17]. And, while harmonic oscillator bases are appropriate for spherical vibrational systems, they are not the most appropriate for rotational-vibrational systems such as diatomic molecules and non-spherical nuclei.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

An algebraic approach to problems with polynomial Hamiltonians on Euclidean spaces

Rowe¹

2005

J. Phys. A: Math. Gen.

View full text Add to dashboard Cite

Explicit expressions are given for the actions and radial matrix elements of basic radial observables on multi-dimensional spaces in a continuous sequence of orthonormal bases for unitary SU(1,1) irreps. Explicit expressions are also given for SO(N )-reduced matrix elements of basic orbital observables. These developments make it possible to determine the matrix elements of polynomial and a other Hamiltonians analytically, to within SO(N ) Clebsch-Gordan coefficients, and to select an optimal basis for a particular problem such that the expansion of eigenfunctions is most rapidly convergent.

show abstract

“…[19]. The low-energy level spectrum of the Hamiltonian (123), calculated with a large value of α [16], is shown in Fig. 8.…”

Section: Cosmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

An algebraic approach to problems with polynomial Hamiltonians on Euclidean spaces

Rowe¹

2005

J. Phys. A: Math. Gen.

View full text Add to dashboard Cite

show abstract

“…, (38) where Φ (2) 1 is the tensor with highest-weight component Φ 1 (γ, Ω), etc., and L = 2n 1 +2n 2 +3n 4 (Sec. 2.3).…”

Section: Evaluation Of Matrix Elementsmentioning

confidence: 99%

“…For higher L, a larger number of F K terms are involved in each calculation. Furthermore, the basis monomials tend to involve higher powers of those generating functions which carry angular momentum (Φ (2) 1 , Φ (2) 2 , and Φ…”

Section: Evaluation Of Matrix Elementsmentioning

confidence: 99%

Construction of spherical harmonics and Clebsch–Gordan coefficients

Caprio

Rowe

Welsh

2009

Computer Physics Communications

Self Cite

View full text Add to dashboard Cite

The SO(5) ⊃ SO(3) spherical harmonics form a natural basis for expansion of nuclear collective model angular wave functions. They underlie the recently-proposed algebraic method for diagonalization of the nuclear collective model Hamiltonian in an SU(1, 1) × SO(5) basis. We present a computer code for explicit construction of the SO(5) ⊃ SO(3) spherical harmonics and use them to compute the Clebsch-Gordan coefficients needed for collective model calculations in an SO(3)-coupled basis. With these Clebsch-Gordan coefficients it becomes possible to compute the matrix elements of collective model observables by purely algebraic methods. Program Summary Title of program: GammaHarmonic

show abstract

“…The value of determining the explicit relationship between the two models is enhanced by the recent development of an algebraic version of the BM [7,8] which makes it possible to execute a full range of BM calculations in bases that range continuously from those of a spherical vibrator to a beta-vibrational Wilets-Jean limit. Our objective in pursuing the relationships between these two models is to discover what can be learned about one model from the other and the extent to which the results of one model can be reproduced by the other.…”

Section: Introductionmentioning

confidence: 99%

The O(6) description of the nuclear rotation

Thiamová

Rowe

2005

Czech J Phys

View full text Add to dashboard Cite

A recently developed algebraic version of the collective model has shown that a full range of Bohr model calculations can be executed in bases that range continuously from those of a spherical vibrator to a beta-vibrational Wilets-Jean limit. Thus, the establishment of close relationships between the algebraic structure of this model and the IBM is of special importance because one can learn from the complementary perspectives they afford. In this paper, we show by calculations that the familiar rotor-gamma vibrational spectra of the Bohr model can be obtained in the IBM by the addition of a scalar cubic in the quadrupole moment operators, of the type considered recently by Van Isacker, to an 0(6) Hamiltonian. Simple fits of the low-lying spectra, electromagnetic transition rates and moments of inertia of the ground and gamma bands of 162Dy and 16SEr are presented. PACS: 21.60.Ev, 21.60.Fw The relationship between the simple interacting boson model (IBM) [1] (by which we mean the so-called IBM-1 version of the model) and the Bohr model (BM) [2] was studied in Ref. [3, 4] and subsequently explored by many authors [5]. Recently, we have investigated the mappings between the related algebraic structures of the IBM and BM [6].The value of determining the explicit relationship between the two models is enhanced by the recent development of an algebraic version of the BM [7, 8] which makes it possible to execute a full range of BM calculations in bases that range continuously from those of a spherical vibrator to a beta-vibrational Wilets-Jean limit. Our objective in pursuing the relationships between these two models is to discover what can be learned about one model from the other and the extent to which the results of one model can be reproduced by the other. In Ref.[6] we show that there are mappings of IBM states into the Hilbert space of the Bohr model, based on group contractions, which define the appropriate correspondence between the states of the two models. However, different mappings are required for the different symmetry limits of the IBM. We also show that, with only minor modification, the new computational tools developed for the Bohr model can be applied also in the IBM.

show abstract

A computationally tractable version of the collective model

Cited by 102 publications

References 35 publications

An algebraic approach to problems with polynomial Hamiltonians on Euclidean spaces

An algebraic approach to problems with polynomial Hamiltonians on Euclidean spaces

Construction of spherical harmonics and Clebsch–Gordan coefficients

The O(6) description of the nuclear rotation

Contact Info

Product

Resources

About