Near-threshold site-selected dissociative ionization of core-excited carbon dioxide
- 14 August 1995
- journal article
- Published by IOP Publishing in Journal of Physics B: Atomic, Molecular and Optical Physics
- Vol. 28 (15) , 3249-3260
- https://doi.org/10.1088/0953-4075/28/15/015
Abstract
The ionization and fragmentation of C and O 1s core excited CO2 has been studied using soft X-rays, threshold electron analysis to define the initial core hole and a triple coincidence technique to examine the final dissociated ion state. The excitation of the O 1s electron results in a single decay channel, CO++O+, corresponding to the breaking of a single C-O bond. At the C 1s edge, the same channel is seen together with a weaker channel, corresponding to the triply ionized three-body fragmentation O++C++O+. Moreover, the angular distribution of ions from the CO++O+ channel is seen to depend on the excited-core state.Keywords
This publication has 19 references indexed in Scilit:
- Dissociation dynamics of core excited N2OThe Journal of Chemical Physics, 1993
- A threshold electron analyser for use in coincidence experimentsMeasurement Science and Technology, 1992
- The undulator beamline at the SRS DaresburyReview of Scientific Instruments, 1992
- Selective fragmentation of nitrous oxide by site-specific N (1s) excitation using soft X-ray synchrotron radiationPhysica Scripta, 1990
- Optimization of soft x-ray monochromators (invited)Review of Scientific Instruments, 1989
- Site specific fragmentation in molecules: Auger-electron ion coincidence studies on N2OThe Journal of Chemical Physics, 1988
- Fragmentation of nitrous oxide by monochromatic soft x raysThe Journal of Chemical Physics, 1986
- The high energy plane grating monochromators at BESSYNuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, 1986
- Site-Specific Fragmentation of Small Molecules Following Soft-X-Ray ExcitationPhysical Review Letters, 1983
- The plane grating and elliptical mirror: A new optical configuration for monochromatorsOptics Communications, 1982