Surface Curvatures and Diffraction Profiles of Sagittaly Bent Laue Crystals

Surface Curvatures and Diffraction Profiles of Sagittaly Bent Laue Crystals

The performance of a bent Laue crystal monochromator crucially depends on the sagittal and meridional bending curvatures of the crystal. To optimize the design of monochromator crystals, the surface curvatures and diffraction profiles of a set of sagittally bent Laue crystals with different aspect r...

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Bibliographic Details
Published in:Journal of applied crystallography Vol. 44; no. 4
Main Authors: Shi, X., Takacs, P., Ghose, S., Zhong, Z., Rehak, M.L., Kaznatcheev, K., Dooryhee, E.
Format: Journal Article
Language:English
Published: United States 17-05-2011
Subjects:
ASPECT RATIO
BENDING
DESIGN
DIFFRACTION
DIMENSIONS
GEOMETRY
INSTRUMENTATION RELATED TO NUCLEAR SCIENCE AND TECHNOLOGY
MONOCHROMATORS
NEUTRON DIFFRACTION
REFLECTIVITY
SIMULATION
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Summary:The performance of a bent Laue crystal monochromator crucially depends on the sagittal and meridional bending curvatures of the crystal. To optimize the design of monochromator crystals, the surface curvatures and diffraction profiles of a set of sagittally bent Laue crystals with different aspect ratios have been studied experimentally by optical metrology and X-ray measurements. The results were confirmed with finite-element analysis using large-deformation theory. The nonlinear relationship between the curvatures necessitates an experimentally determined parameter in the theoretical modeling of the diffraction profiles. By taking into account the local stress and the aspect ratio of the sagittally bent Laue crystal, the modified analytical approach successfully predicts the rocking-curve width and the integrated reflecting power. The effect of extreme sagittal bending on the rocking curve is also discussed. To retain high reflectivity, the bending curvature should not exceed its critical value for the specified crystal geometry. Furthermore, the uniformity of the bending curvatures across the crystal surface has been examined, which suggests that the minimum crystal dimension should be approximately twice the size of the beam footprint.
Bibliography:DE-AC02-98CH10886
BNL-95421-2011-JA
DOE - OFFICE OF SCIENCE
ISSN:0021-8898
1600-5767
DOI:10.1107/S0021889811018711