Towards a relativistically covariant many-body perturbation theory - With numerical implementation to helium-like ions
Abstract
The experimental results for simple atomic systems have become more and more accurate and in order to keep up with the experimental achievements the theoretical procedures have to be refined. Recent accurate experimental results obtained for helium-like ions in the low- and moderate-Z regions proclaim the importance of theoretical calculations that combines relativistic, QED and electron correlation effects. On the basis of these premises the relativistically covariant many-body perturbation procedure is developed and it is this development that is introduced in this thesis. The new theoretical procedure treats relativistic, QED and electron correlation effects on the same footing.
The numerical implementation leads to a systematic procedure similar to the atomic coupled-cluster approach, where the energy contribution of QED effects are evaluated with correlated relativistic wave functions. The effects of QED are also included in the resulting numerical wave functions of the procedure, which can be reintroduced with an approach of iteration for calculations of new higher-order effects.
The first numerical implementation of the procedure to the groundstate for a number of helium-like ions in the range Z = 6 − 50 of the nuclear charge, indicates the importance of combined effects of QED and correlation in the low- and moderate-Z regions. The results show also that the effect of
electron correlation on first-order QED-effects for He-like ions in the low and moderate-Z regions dominates over second-order QED-effects.
Parts of work
I. Many-body-QED perturbation theory: Connection to the two-electron Bethe-Salpeter equation. Can. J. Phys., 83, 183-218, 2005. ::doi::10.1139/P05-027 II. Many-body procedure for energy-dependent perturbation: Merging many-body perturbation theory with QED. Phys. Rev. A., 73, 062502, 2006. ::doi::10.1103/PhysRevA.73.062502
Degree
Doctor of Philosophy
University
Göteborgs universitet. Naturvetenskapliga fakulteten
Institution
Department of Physics ; Institutionen för fysik
Disputation
Fredagen den 23 april 2010, kl. 13.15, Kollektorn, MC2, Chalmers tekniska högskola, Göteborg
Date of defence
2010-04-23
daniel.hedendahl@physics.gu.se
Date
2010-03-30Author
Hedendahl, Daniel
Keywords
many-body perturbation theory
bound state QED
helium-like ions
Green's operator
covariant evolution operator
combined effects of QED and correlation
atomic structure calculations
Publication type
Doctoral thesis
ISBN
978-91-628-8071-2
Language
eng