X-Ray Standing Waves at the Total Reflection Condition: Direct Method and Coherence Effects
Abstract
Fresnel theory is used to derive the complex electric-fields above and below an X-ray reflecting interface that separates two materials with differing indices of refraction. The interference between the incident and reflected waves produces an X-ray standing wave (XSW) above the reflecting interface. The XSW intensity modulation is strongly enhanced by the total external reflection (TR) condition, which occurs at incident angles less than the critical angle. At these small milliradian incident angles the XSW period (lambda/2theta) becomes very large, which makes the TR-XSW an ideal probe for studying low-density structures that extend 1 to 1000 nm above the reflecting interface. Fourier inversion of the XSW induced modulation in the X-ray fluorescence (XRF) yield from a specific atomic distribution within the overlayer directly produces a model-independent 1-D atomic density profile. The modulation can also be used to analyze the degree of coherence in the incident X-ray beam.
Cite
@article{arxiv.0908.2115,
title = {X-Ray Standing Waves at the Total Reflection Condition: Direct Method and Coherence Effects},
author = {Michael J. Bedzyk},
journal= {arXiv preprint arXiv:0908.2115},
year = {2009}
}
Comments
13 pages, 10 figures, Chapter preprint from Series on Synchrotron Radiation Techniques and Applications -Vol. 7, The X-Ray Standing Wave Technique: Principles and Applications, edited by Jorg Zegenhagen and Alexander Kazimirov, World Scientific Publishing Co. ISBN:978-981-277-900-7