Premium
X‐ray Multiple Diffraction in Renninger Scanning Mode: Simulation of Data Recorded using Synchrotron Radiation
Author(s) -
Sasaki J. M.,
Cardoso L. P.,
Campos C.,
Roberts K. J.,
Clark G. F.,
Pantos E.,
Sacilotti M. A.
Publication year - 1996
Publication title -
journal of applied crystallography
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.429
H-Index - 162
ISSN - 1600-5767
DOI - 10.1107/s0021889896001641
Subject(s) - synchrotron radiation , diffraction , optics , polarization (electrochemistry) , synchrotron , beam (structure) , radiation , materials science , physics , chemistry
The application limit of the MULTX program for predicting Renninger‐scanning X‐ray multiple diffraction data is extended in order to simulate Renninger scans for semiconductor single‐crystal and heteroepitaxial structures recorded using synchrotron radiation. The experimental synchrotron‐radiation Renninger scan for InP(006) bulk material is taken as the standard to analyse the effects of both the polarization factor and diffracted‐beam path length. The polarization of the synchrotron‐radiation beam is considered using a matrix approach. The diffracted‐beam path length involved in the surface secondary beam cases is analysed taking into account the dynamical theory for perfect crystals and the kinematical theory as the limit of the dynamical case for thin crystals. Renninger scans of AlGaInAs quaternary layer structures, simulated with the MULTX program, show a very good agreement ( R = 0.085) with the corresponding experimental data.