Integral representation of the diffracted intensity from one-dimensional stepped surfaces and epitaxial layers

15 September 1985

journal article
research article
Published by AIP Publishing in Journal of Applied Physics

Vol. 58 (6) , 2184-2189
https://doi.org/10.1063/1.335985

Abstract

An integral representation of the diffracted intensity from one-dimensional stepped surfaces and overlayers is obtained based on the single-scattering (kinematic) theory. We find exact solutions for an arbitrary terrace or island size distribution on stepped surfaces or epitaxial layers in an extremely simple manner. This theory greatly expands the utility of the kinematic analysis of electron, atom, or grazing x-ray diffraction data. A particularly useful area of application is the quantitative study of the nucleation kinetics during the epitaxial growth of thin films. Several surface ordering models are discussed in terms of this simplified approach.

This publication has 32 references indexed in Scilit:

Scattering of He, Ne, Ar, $H_{2}$ , and $N_{2}$ from Cu(110)
Physical Review B, 1985
He scattering study of the nucleation and growth of Cu(100) from its vapor
Physical Review B, 1985
A method for the calculation of LEED angular profiles to estimate overlayer spacings and island size distributions
Journal of Vacuum Science & Technology A, 1984
Direct Determination of the Au(110) Reconstructed Surface by X-Ray Diffraction
Physical Review Letters, 1983
Diffraction by crystals with planar domains
Acta Crystallographica Section A, 1981
Observation of selective desorption of one-phonon inelastically scattered He atoms from a LiF crystal surface
The Journal of Chemical Physics, 1981
Diffuse LEED intensities of disordered crystal surfaces: III. LEED investigation of the disordered (110) surface of gold
Surface Science, 1978
Diffuse LEED intensities of disordered crystal surfaces: II. Multiple scattering on disordered overlayers
Surface Science, 1978
Diffuse LEED intensities of disordered crystal surfaces: I. Correlations between statistics and multiple diffraction
Surface Science, 1978
Dynamical theory of low-energy-electron diffraction from disordered overlayers. II. Application to one-dimensional adsorbates
Physical Review B, 1974