Transition probabilities in the lithium isoelectronic sequence
- 1 October 1973
- journal article
- Published by IOP Publishing in Journal of Physics B: Atomic and Molecular Physics
- Vol. 6 (10) , 1953-1966
- https://doi.org/10.1088/0022-3700/6/10/011
Abstract
The nuclear-charge expansion method is used to calculate multiplet strengths, correct through first order, for 1s2nl2L-1s2ml'2L' dipole transitions in lithium-like ions for all n,m<or=4. Two distinct procedures, which give results in very close agreement, are used and a modified screening approximation is employed to increase the rate of convergence of the expansions. From these calculated values and experimental energy differences, oscillator strengths and radiative lifetimes for a range of atomic ions are predicted and compared with other available data.Keywords
This publication has 35 references indexed in Scilit:
- Cascade-Induced Alignment Changes of Intensity-Decay CurvesJournal of the Optical Society of America, 1972
- Beam-Foil Study of Nitrogen in the Vacuum UltravioletJournal of the Optical Society of America, 1972
- Lifetimes an Oscillator Strengths in Spectra of Be, B and CPhysica Scripta, 1971
- Transition probability and oscillator strength by perturbation theory: 1s3p1,3P-1s3d1,3D Transition in helium isoelectronic sequenceInternational Journal of Quantum Chemistry, 1970
- Mean-Life Measurements of Excited Electronic States in Neutral and Ionic Species of Beryllium and BoronPhysical Review B, 1969
- Hartree-Fock multiplet strengths of 1s24l 2L-1s24l′ 2L′ transitions of the lithium isoelectronic sequenceJournal of Physics B: Atomic and Molecular Physics, 1969
- Absolute multiplet strengths for 4L-4L? transitions of the helium sequenceMolecular Physics, 1969
- Mean Lives of Some Excited Levels of Li i and Li ii*Journal of the Optical Society of America, 1969
- Transition probability and oscillator strength by perturbation theory: 1s3p1,3P−1s3d1,3D transition in helium isoelectronic sequenceInternational Journal of Quantum Chemistry, 1969
- Oscillator strengths by perturbation theoryMolecular Physics, 1968