Photoionization of atomic hydrogen in an electric field
- 1 September 1991
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review A
- Vol. 44 (5) , 3060-3082
- https://doi.org/10.1103/physreva.44.3060
Abstract
The photoionization cross section of atomic hydrogen in an electric field can be understood as the sum of resonance contributions. Each contribution is proportional to the imaginary part of the square of a complex transition-dipole matrix element divided by an energy denominator and has a naturally asymmetric line shape. The main features of experiments, including asymmetry of the lines, blue shift of maxima with respect to calculated resonances near zero energy, ‘‘field-induced’’ structure above zero energy, and increasing ‘‘background’’ that begins above the classical saddle-point energy, are reproduced via variational calculations of the resonance energies and wave functions in parabolic coordinates.Keywords
This publication has 37 references indexed in Scilit:
- Positive-energy spectrum of the hydrogen atom in a magnetic fieldPhysical Review Letters, 1991
- Resonance and interference phenomena in the photoionisation of a hydrogen atom in a uniform electric field. III. Comparison with recent experimental and theoretical resultsJournal of Physics B: Atomic, Molecular and Optical Physics, 1990
- Stark effect and field ionisation of atomic hydrogenJournal of Physics B: Atomic and Molecular Physics, 1986
- The lamb shift in hydrogen-like atoms, 1 ⩽ Z ⩽ 110Atomic Data and Nuclear Data Tables, 1985
- Asymmetry of field-induced shape resonances in hydrogenPhysical Review A, 1985
- Shape Resonances in the Hydrogen Stark Effect in Fields up to 3 MV/cmPhysical Review Letters, 1984
- Dilation analyticity in constant electric fieldCommunications in Mathematical Physics, 1979
- Resonances in Stark effect and perturbation theoryCommunications in Mathematical Physics, 1978
- Coupling constant analyticity for the anharmonic oscillatorAnnals of Physics, 1970
- Theory of nuclear reactionsNuclear Physics, 1961