English

Recursion Method for Deriving Energy-Independent Effective Interaction

Nuclear Theory 2015-06-18 v1

Abstract

The effective-interaction theory has been one of the useful and practical methods for solving nuclear many-body problems based on the shell model. Various approaches have been proposed which are constructed in terms of the so-called Q^\widehat{Q} box and its energy derivatives introduced by Kuo {\it et al}. In order to find out a method of calculating them we make decomposition of a full Hilbert space into subspaces (the Krylov subspaces) and transform a Hamiltonian to a block-tridiagonal form. This transformation brings about much simplification of the calculation of the Q^\widehat{Q} box. In the previous work a recursion method has been derived for calculating the Q^\widehat{Q} box analytically on the basis of such transformation of the Hamiltonian. In the present study, by extending the recursion method for the Q^\widehat{Q} box, we derive another recursion relation to calculate the derivatives of the Q^\widehat{Q} box of arbitrary order. With the Q^\widehat{Q} box and its derivatives thus determined we apply them to the calculation of the EE-independent effective interaction given in the so-called Lee-Suzuki (LS) method for a system with a degenerate unperturbed energy. We show that the recursion method can also be applied to the generalized LS scheme for a system with non-degenerate unperturbed energies. If the Hilbert space is taken to be sufficiently large, the theory provides an exact way of calculating the Q^\widehat{Q} box and its derivatives. This approach enables us to perform recursive calculations for the effective interaction to arbitrary order for both systems with degenerate and non-degenerate unperturbed energies.

Keywords

Cite

@article{arxiv.1402.2723,
  title  = {Recursion Method for Deriving Energy-Independent Effective Interaction},
  author = {Kenji Suzuki and Hiroo Kumagai and Ryoji Okamoto and Masayuki Matsuzaki},
  journal= {arXiv preprint arXiv:1402.2723},
  year   = {2015}
}

Comments

24 pages, submitted to Phys.Rev. C

R2 v1 2026-06-22T03:06:23.314Z