Three-dimensional reconstruction of intragranular strain and orientation in polycrystals by near-field X-ray diffraction

•Novel algorithm reconstructs sub-grain orientation and strain fields in polycrystals.•Non-destructive in-situ scanning in 3D within minutes by X-ray diffraction imaging.•Iterative ITF solves non-linear tomography problem with unknown projection geometry.•Models and representations of 3D deformation...

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Bibliographic Details
Published in:Current opinion in solid state & materials science 2020-10, Vol.24 (5), p.100851, Article 100851
Main Authors: Reischig, Péter, Ludwig, Wolfgang
Format: Article
Language:English
Subjects:
3DXRD
Condensed Matter
Crystallography
Deformation
Diffraction contrast
Engineering Sciences
Grain mapping
Intragranular
Iterative tensor field
Materials
Materials Science
Orientation
Physics
Polycrystal
Signal and Image processing
Strain
Stress
Tomography
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Summary:•Novel algorithm reconstructs sub-grain orientation and strain fields in polycrystals.•Non-destructive in-situ scanning in 3D within minutes by X-ray diffraction imaging.•Iterative ITF solves non-linear tomography problem with unknown projection geometry.•Models and representations of 3D deformations for microstructure mapping.•Feasible coupling with crystal plasticity FEM or mechanical equilibrium condition. A theoretical framework is proposed for simultaneous reconstruction of the three-dimensional grain shapes, intragranular strain and orientation fields inside polycrystals from near-field X-ray diffraction images, using box beam illumination. The approach, named Iterative Tensor Field (ITF) reconstruction, uses a tensor field representation and a kinematical forward simulation model to reproduce the measured diffraction signal from individual grains. The framework establishes a link between the local deformation components inside the grains and the intensities of the diffraction signal in the measured images by forming a local linear problem. This is solved using a large scale linear optimisation method in every main iteration of the underlying non-linear problem. The optimisation enforces smooth gradients and the objective function may include regularisation constraints of static equilibrium or input from a Crystal Plasticity FEM simulation. The method has modest computational requirements and enables efficient scanning of millimetre or sub-millimetre sized specimens. Results on experimental data measured on a Gum metal specimen are presented, which demonstrate convergence and the feasibility of the approach. The mathematical formulation, data representation and challenges in the reconstruction and validation are discussed. The physical aspects of the contrast phenomenon, the deformation sensitivity of the technique, and potential means of error assessment are described. A number of alternative concepts for a polycrystalline deformation model and potential solvers are also presented.
ISSN:1359-0286
DOI:10.1016/j.cossms.2020.100851