Properties of metastable alkaline-earth-metal atoms calculated using an
  accurate effective core potential

A. Dalgarno; A. R. Edmonds; C. E. Moore; C. J. Pethick; Chris H. Greene; D. P. Craig; G. H. Golub; G. zu Putlitz; H. Katori; I. I. Sobelman; J. D. Jackson; K. J. Bathe; K. J. Bathe; Kevin V. Christ; M. H. Mittleman; R. B. Lehoucq; R. Drozdowski; R. G. Garstang; R. Marrus; R. N. Zare; Robin Santra; U. Fano; X. Xu

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Properties of metastable alkaline-earth-metal atoms calculated using an accurate effective core potential

Authors: A. Dalgarno
A. R. Edmonds
C. E. Moore
C. J. Pethick
Chris H. Greene
D. P. Craig
G. H. Golub
G. zu Putlitz
H. Katori
I. I. Sobelman
J. D. Jackson
K. J. Bathe
K. J. Bathe
Kevin V. Christ
M. H. Mittleman
R. B. Lehoucq
R. Drozdowski
R. G. Garstang
R. Marrus
R. N. Zare
Robin Santra
U. Fano
X. Xu
Publication date: 4 December 2003
Publisher: 'American Physical Society (APS)'
Doi

Abstract

The first three electronically excited states in the alkaline-earth-metal atoms magnesium, calcium, and strontium comprise the (nsnp) triplet P^o_J (J=0,1,2) fine-structure manifold. All three states are metastable and are of interest for optical atomic clocks as well as for cold-collision physics. An efficient technique--based on a physically motivated potential that models the presence of the ionic core--is employed to solve the Schroedinger equation for the two-electron valence shell. In this way, radiative lifetimes, laser-induced clock shifts, and long-range interaction parameters are calculated for metastable Mg, Ca, and Sr.Comment: 13 pages, 9 table

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