Comparison of Average-Potential Models and Binary-Collision Models of Axial Channeling and Blocking
- 1 March 1970
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review B
- Vol. 1 (5), 2063-2069
- https://doi.org/10.1103/physrevb.1.2063
Abstract
A comparison is made of three types of calculations of the axial "channeling dip": the large decrease in yield of close-encounter processes for energetic ions incident on a single crystal parallel to a low-index direction. The models, indicated as (1) the binary-collision model, (2) the halfway-plane model, and (3) the continuum model, are used to calculate the dip for two standard cases corresponding to recent experiments. The methods are compared as to treatment of potential and treatment of thermal vibrations. The ease of calculation versus quantitative accuracy for the different methods is discussed, and finally the agreement with experimental results is briefly reviewed.Keywords
This publication has 17 references indexed in Scilit:
- Location of Shoulders in Channeling PhenomenaPhysical Review B, 1968
- Channeling Effects in the Energy Loss of 3-11-MeV Protons in Silicon and Germanium Single CrystalsPhysical Review B, 1967
- Rutherford Scattering of Protons in the Surface Layers of a Tungsten Single CrystalPhysical Review Letters, 1967
- Quantal treatment of directional effects for energetic charged particles in crystal latticesNuclear Physics A, 1967
- Interpretation of the anisotropy of α particle emission from a monocrystalline sourcePhysics Letters, 1965
- Anisotropic Effects in Interactions of Energetic Charged Particles in a Crystal LatticePhysical Review Letters, 1965
- Blocking Effects in the Emergence of Charged Particles from Single CrystalsPhysical Review Letters, 1965
- The penetration of energetic ions through the open channels in a crystal latticePhilosophical Magazine, 1963
- Long-Range Channeling Effects in Irradiated CrystalsJournal of Applied Physics, 1963
- On the Nature of Radiation Damage in MetalsJournal of Applied Physics, 1954