Dynamical Electron Backscatter Diffraction Patterns. Part I: Pattern Simulations

Callahan, Patrick G.; Graef, Marc De

doi:10.1017/s1431927613001840

Cited by 126 publications

(111 citation statements)

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“…6,7 Because of the increased information content which is provided by dynamical electron diffraction in EBSD Kikuchi patterns, the detailed simulation and analysis of the respective effects is becoming more and more important. 8 Typical applications include EBSD-based lattice strain analysis, 9 EBSD image segmentation, 10,11 and the analysis of orientation relationships in phase transformations. 12 Moreover, EBSD-based chirality determination was recently demonstrated.…”

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confidence: 99%

Point-group sensitive orientation mapping of non-centrosymmetric crystals

Winkelmann

Nolze

2015

Applied Physics Letters

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Articles you may be interested inDirect microscopic correlation of crystal orientation and luminescence in spontaneously formed nonpolar and semipolar GaN growth domains Appl. Phys. Lett. 96, 172102 (2010); 10.1063/1.3386539 m -plane ( 10 1 ̱ 0 ) InN heteroepitaxied on ( 100 ) -γ -LiAlO 2 substrate: Growth orientation control and characterization of structural and optical anisotropy Large crystal grain niobium thin films deposited by energetic condensation in vacuum arc

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confidence: 99%

Point-group sensitive orientation mapping of non-centrosymmetric crystals

Winkelmann

Nolze

2015

Applied Physics Letters

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“…The quality of this model is demonstrated in [10], where it produces simulated patterns close to experimental patterns. For each orientation, the process consists of three steps.…”

Section: Construction Of Diffraction Pattern Dictionarymentioning

confidence: 84%

EBSD image segmentation using a physics-based forward model

Park

Wei

Graef

et al. 2013

2013 IEEE International Conference on Image Processing

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We propose a segmentation and anomaly detection method for electron backscatter diffraction (EBSD) images. In contrast to conventional methods that require Euler angles to be extracted from diffraction patterns, the proposed method operates on the patterns directly. We use a forward model implemented as a dictionary of diffraction patterns generated by a detailed physics-based simulation of EBSD. The combination of full diffraction patterns and a dictionary allows anomalies to be detected at the same time as grains are segmented, and also increases robustness to noise and instrument blur. The proposed method is demonstrated on a sample of the Ni-base alloy IN100.

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“…Because of the potentially small size of this selected area, local changes to the lattice parameters can be identified by observing changes in the positions of HOLZ lines. Prior work has established a dictionary-based mapping technique for SACPs, which is used to identify an orientation for any given SACP based on the imaging parameters as well as the sample structure and composition [1].Dictionary indexing of SACPs is accomplished by simulating patterns for all possible Euler angle combinations, with some finite step size in orientation space, and taking the dot product of experimental and simulated patterns [2]. The maximum value of this dot product is then taken to be the best fit for the experimental pattern.…”

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“…Dictionary indexing of SACPs is accomplished by simulating patterns for all possible Euler angle combinations, with some finite step size in orientation space, and taking the dot product of experimental and simulated patterns [2]. The maximum value of this dot product is then taken to be the best fit for the experimental pattern.…”

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Automated Acquisition and Analysis of Selected Area Electron Channeling Patterns in an FEG-SEM

et al. 2017

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Fine details of crystalline structure, including local lattice parameters, shifts due to strain, and compositional variation, can be investigated by analyzing the positions of higher-order Laue zone (HOLZ) lines. Micrographs displaying these lines are often captured by convergent-beam electron diffraction (CBED), an imaging modality in the TEM. However, these lines can also be acquired in selected-area electron channeling patterns (SACP), a diffraction modality in the SEM that makes use of backscattered electrons. SEM holds several advantages over TEM, including simpler operation and minimal sample preparation, as well as the ability to analyze larger sample areas.SACPs differ from conventional electron channeling patterns in that the point of incidence of the beam on the sample surface does not change over the course of the beam rocking. Rather, the angle of incidence is varied while the beam pivots on a single spot. Because of the potentially small size of this selected area, local changes to the lattice parameters can be identified by observing changes in the positions of HOLZ lines. Prior work has established a dictionary-based mapping technique for SACPs, which is used to identify an orientation for any given SACP based on the imaging parameters as well as the sample structure and composition [1].Dictionary indexing of SACPs is accomplished by simulating patterns for all possible Euler angle combinations, with some finite step size in orientation space, and taking the dot product of experimental and simulated patterns [2]. The maximum value of this dot product is then taken to be the best fit for the experimental pattern. Automated acquisition of SACPs over a large area is of interest for use in the characterization of materials with compositional gradients, fine grain structures, or variations in defect morphology. Using scripts to interface with the microscope, automated acquisition of patterns over a large grid has been demonstrated. The step size on such grids is limited mainly by the size of the selected area and the precision of the microscope stage. As such, tuning of the microscope to reduce the size of the selected area is an ongoing process, in addition to assessing the accuracy and repeatability of stage movement [3].Once channeling patterns for each point have been captured, dictionary mapping provides Euler angles for each point, which can then be used to produce an inverse pole figure (IPF) orientation mapping similar to that obtained from electron backscatter diffraction (EBSD). Demonstrating automated acquisition and indexing of SACPs is a necessary step towards automated imaging of crystalline defects. Such imagining requires analyzing SACPs and tilting to a specific g vector to highlight dislocations. Future work will implement automated tilting and rotation for such dislocation imaging. Comparison of experimentally produced and indexed SACP orientation maps with EBSD IPF maps show similar results for both techniques [4].

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Dynamical Electron Backscatter Diffraction Patterns. Part I: Pattern Simulations

Cited by 126 publications

References 21 publications

Point-group sensitive orientation mapping of non-centrosymmetric crystals

Point-group sensitive orientation mapping of non-centrosymmetric crystals

EBSD image segmentation using a physics-based forward model

Automated Acquisition and Analysis of Selected Area Electron Channeling Patterns in an FEG-SEM

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