Atomic collisions on solid surfaces /
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| Imprint: | Amsterdam ; New York : North-Holland, 1993. |
|---|---|
| Description: | xiii, 664 p. : ill. ; 25 cm. |
| Language: | English |
| Subject: | |
| Format: | Print Book |
| URL for this record: | http://pi.lib.uchicago.edu/1001/cat/bib/2348679 |
Table of Contents:
- 1. General. 1. Conditions of applicability of classical mechanics. 2. Laws of momentum and energy conservation. 3. Deflection function. 4. Interaction potentials. 5. Differential scattering cross sections. 6. Inelastic energy losses. 7. Binary scattering model
- 2. Computer simulation of surface collisions. 1. Simulation techniques. 2. Particle dynamics in the binary collision model. 3. Crystal models; inclusion of thermal vibrations. 4. Algorithm and program of calculation
- 3. Single and double scattering. 1. Single-scattering effect. 2. Double-scattering effect. 3. Double scattering from a single crystal. 4. Screening and blocking in two-atom scattering. 5. Energy distribution of scattered projectiles. 6. Relative probability of double scattering. 7. Double scattering in nuclei. 8. Ion scattering from a diatomic molecule. 9. Double scattering from polycrystals. 10. Enhancement of [actual symbol not reproducible] backscattering
- 4. Atomic row model. 1. String model. 2. Scattering from a discrete atomic row. 3. Spatial distribution of scattered ions. 4. Effect of thermal vibrations and interaction potential. 5. Three-atom scattering model. 6. Atomic row effect for an inverse mass ratio. 7. Ion scattering from complex composition surfaces
- 5. Ion scattering in semichannels. 1. Spatial and energy distribution. 2. Ion focusing effect. 3. Subsurface channeling and hyperchanneling. 4. Azimuthal anisotropy in scattering. 5. Elastic and inelastic energy losses
- 6. Atom scattering from a nonideal surface. 1. Surface of a solid. 2. State of the surface after ion bombardment. 3. Effect of the surface structure on the scattered ion distribution
- 7. Scattering of light atoms. 1. Energy spectra of scattered light atoms. 2. Single and double scattering. 3. Energy distribution of scattered atoms. 4. Surface peak
- 8. Charge state of atoms scattered by solid surfaces. 2. Charge state of ions scattered by metal surfaces. 3. The role of violent single collisions. 4. Charge state of light atoms. 5. Orientational effects in the charge state of ions scattered by a single crystal. 6. Charge state of alkali atoms scattered by solid surfaces
- 9. Scattering of swift molecules by solid surfaces. 2. Scattering of swift molecules within the elastic collision model. 3. Highest rotational and vibrational excitation of swift diatomic molecules scattered by solid surfaces. 4. Energy distribution and ionization degree of scattered atoms under bombardment of molecules. 5. Molecule dissociation via electron transition at grazing scattering
- 10. Sputtering of clusters and biomolecules under ion bombardment. 2. Small-cluster sputtering. 3. Large-cluster sputtering. 4. Desorption of biomolecules under heavy-ion bombardment
- 11. Auger processes in kinetic electron emission. 2. Kinetic electron emission. 3. Shell effects. 4. Orientational effects in ion-induced Auger electron emission
- 12. Interaction of multiple-charged ions with surfaces. 2. Electron emission. 3. Sputtering of nonmetals under slow multiple-charged ions through Coulomb explosion. 4. Identification of multiple-charged ions
- 13. Application of ion scattering to surface diagnostics. 1. Analysis of surface composition. 2. Structural analysis of crystal surfaces. 3. Adatom identification and location.
