Next:
Acknowledgements
Up:
root
Previous:
root
Contents
Contents
Introduction
Molecular ions
Emission Spectroscopy
Infrared and Microwave studies
Laser Magnetic Resonance
Direct absorption techniques
Photodissociation of molecular ions
Ion Beam Techniques
Experimental
Introduction
Features of fast ion beam experiments
Mass selection
Doppler Effects
Lifetimes and Line shapes
Source Conditions
Laser/Ion Beam Overlap
Apparatus
Overview
Ion source
Flight Region
Vacuum System
Detection Electronics
Laser System
Overview
Ring Dye Laser
Energy Releases
Conversion of momentum to energy Release
Centre of Mass Energy Release
Resolution of the Electromagnetic Sector
Theory of the spectroscopy of diatomic molecules
Introduction
Spectroscopic theory
Coupling of Angular Momentum
Lambda doubling
Predissociation
Born Oppenheimer Approximation
Predissociation by tunnelling
Feshbach resonances
Potential energy surface creation and solving the Schrödinger equation using computational methods
Calculation of Potential Surfaces from Spectroscopic Data (RKR)
Calculation of Eigenvalues, Transitions and Frank-Condon Factors (LEVEL 6.0)
Design and construction of a new ion source
Introduction
Jet cooling of ion beams
Overview
Background
Related Literature
Experimental
Vacuum Apparatus
Ion source
Skimmer and ion optics
Alignment of the nozzle to the skimmer
Mixtures of Gases
Review of O
2
+
Introduction
States and Spectroscopy of O
2
+
Experimental Setup
Results
Jet apparatus results
Estimation of temperature
Conclusions
Assigned line positions
Non linear least squares fit residuals
Calculated potentials for the X and A states.
Unassigned line positions
Bibliography
Tim Gibbon
1999-09-06