RPA vs. exact shell-model correlation energies

A. Klein; A. Poves; B.H. Wildenthal; Calvin W. Johnson; D.J. Rowe; E.R. Marshalek; F. Tondeur; G.F. Bertsch; H. Kamada; H.J. Lipkin; Ionel Stetcu; J.C. Parikh; K. Hagino; K. Hagino; N. Dinh Dang; N. Ullah; P. Möller; P. Navratil; P. Navratil; P. Schuck; R.B. Wiringa; R.M. Dreizler; T.T.S. Kuo; W.E. Ormand; Y. Aboussir; Y.R. Shimizu

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RPA vs. exact shell-model correlation energies

Authors: A. Klein
A. Poves
B.H. Wildenthal
Calvin W. Johnson
D.J. Rowe
E.R. Marshalek
F. Tondeur
G.F. Bertsch
H. Kamada
H.J. Lipkin
Ionel Stetcu
J.C. Parikh
K. Hagino
K. Hagino
N. Dinh Dang
N. Ullah
P. Möller
P. Navratil
P. Navratil
P. Schuck
R.B. Wiringa
R.M. Dreizler
T.T.S. Kuo
W.E. Ormand
Y. Aboussir
Y.R. Shimizu
Publication date: 9 May 2002
Publisher: 'American Physical Society (APS)'
Doi

Abstract

The random phase approximation (RPA) builds in correlations left out by mean-field theory. In full 0-hbar-omega shell-model spaces we calculate the Hartree-Fock + RPA binding energy, and compare it to exact diagonalization. We find that in general HF+RPA gives a very good approximation to the ``exact'' ground state energy. In those cases where RPA is less satisfactory, however, there is no obvious correlation with properties of the HF state, such as deformation or overlap with the exact ground state wavefunction.Comment: 6 pages, 7 figures, submitted to Phys Rev

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