Precise solution of few-body problems with stochastic variational method
  on correlated Gaussian basis

A. B. Volkov; A. Kievsky; A. Kievsky; A. Kievsky; A. M. Frolov; A. Ono; A. Ore; A. Ore; A. P. Mills; A. Yeremin; B. S. Pudliner; D. B. Kinghorn; D. Brink; D. R. Thompson; E. A. Hylleraas; G. Erens; H. De Raedt; H. Feldmeier; H. Horiuchi; H. Kamada; H. Kameyama; I. E. Lagaris; I. R. Afnan; I. Reichstein; J. A. Wheeler; J. Carlson; J. Carlson; J. L. Ballot; J. L. Basdevant; J. L. Friar; K. Arai; K. E. Schmidt; K. Singer; K. Varga; K. Varga; K. Varga; K. Wildermuth; M. H. Kalos; M. Kamimura; M. Kamimura; M. Kamimura; N. W. Schellingerhout; P. M. Kozlowski; P. M. Kozlowski; P. O. Löwdin; R. A. Malfliet; R. B. Wiringa; R. B. Wiringa; R. G. Lovas; S. A. Alexander; S. Ali; S. F. Boys; S. Fantoni; V. I. Kukulin; W. Glöckle; Y. K. Ho; Y. K. Ho; Y. Suzuki; Y. Suzuki

research

Precise solution of few-body problems with stochastic variational method on correlated Gaussian basis

Abstract

Precise variational solutions are given for problems involving diverse fermionic and bosonic

N=2-7

-body systems. The trial wave functions are chosen to be combinations of correlated Gaussians, which are constructed from products of the single-particle Gaussian wave packets through an integral transformation, thereby facilitating fully analytical calculations of the matrix elements. The nonlinear parameters of the trial function are chosen by a stochastic technique. The method has proved very efficient, virtually exact, and it seems feasible for any few-body bound-state problems emerging in nuclear or atomic physics.Comment: 39 pages (revtex) + 3 figures (appended as compressed uuencoded .ps files

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