Open AccessEfficient modeling of Bragg coherent x-ray nanobeam diffraction
Author(s) -
S. O. Hruszkewycz,
Martin V. Holt,
Marc Allain,
Virginie Chamard,
S. M. Polvino,
Conal E. Murray,
P. H. Fuoss
Publication year - 2015
Publication title -
optics letters
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.524
H-Index - 272
eISSN - 1071-2763
pISSN - 0146-9592
DOI - 10.1364/ol.40.003241
Subject(s) - optics , coherent diffraction imaging , diffraction , bragg's law , diffraction topography , fresnel diffraction , ptychography , fourier transform , acousto optics , scattering , bragg peak , materials science , x ray crystallography , diffraction efficiency , fresnel zone , wide angle x ray scattering , physics , diffraction grating , phase retrieval , beam (structure) , small angle neutron scattering , neutron scattering , quantum mechanics
X-ray Bragg diffraction experiments that utilize tightly focused coherent beams produce complicated Bragg diffraction patterns that depend on scattering geometry, characteristics of the sample, and properties of the x-ray focusing optic. Here, we use a Fourier-transform-based method of modeling the 2D intensity distribution of a Bragg peak and apply it to the case of thin films illuminated with a Fresnel zone plate in three different Bragg scattering geometries. The calculations agree well with experimental coherent diffraction patterns, demonstrating that nanodiffraction patterns can be modeled at nonsymmetric Bragg conditions with this approach--a capability critical for advancing nanofocused x-ray diffraction microscopy.
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