Modelling Electron Channeling Contrast Intensity of Stacking Fault and Twin Boundary Using Crystal Thickness Effect

Kriaa, Hana; Guitton, Antoine; Maloufi, Nabila

doi:10.3390/ma14071696

Cited by 7 publications

(3 citation statements)

References 30 publications

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“…This is analogous to the well documented fringe contrast observable in TEM [57][58][59] and matches the contrast reported for stacking faults in metals. 38 This contrast behavior is caused by the change of the phase shift (2 Â π Â g Â u, with the diffraction vector g and the displacement vector u) along the inclined basal plane stacking fault 60 and depends on the inclination angle (% 32:1 ) and extinction distance in the material. It is notable, that some BSF lines show contrast inversion along the intersection line with the surface within the same diffraction condition, similar to observations made by Zakharov et al 57 We attribute this behavior to imaging two different I 1 BSFs with the opposite displacement vector u.…”

Section: Resultsmentioning

confidence: 99%

Defect characterization of {101¯3} GaN by electron microscopy

Kusch

Frentrup

et al. 2022

Journal of Applied Physics

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Advances in obtaining untwinned (10[Formula: see text]3)-oriented semi-polar GaN enable a new crystal orientation for the growth of green and red LED structures. We present a scanning electron microscopy study that combines the structural characterization of electron channeling contrast imaging with the optical characterization of cathodoluminescence hyperspectral imaging on a [Formula: see text] GaN layer. An extensive defect analysis revealed that the dominant defects consist of basal plane stacking faults (BSFs), prismatic stacking faults, partial dislocations, and threading dislocations. With a defect density of about an order of magnitude lower than in comparable. The optical properties of the defects have been characterized from 10 to 320 K, showing BSF luminescence at room temperature indicating a reduced density of non-radiative recombination centers in the as-grown samples compared to established semi- and non-polar orientations. Our findings suggest that growth along (10[Formula: see text]3) has the potential for higher radiative efficiency than established semi-polar orientations.

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Section: Resultsmentioning

confidence: 99%

Defect characterization of {101¯3} GaN by electron microscopy

Kusch

Frentrup

et al. 2022

Journal of Applied Physics

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“…Defects are recognised by ECCI based on the difference of channelling contrasts. [3][4][5][6][7] The spatial resolution of ECCI is also poor (2-5 μm). 3 Even the selected area electron channelling pattern (SACP) technique can obtain resolution only to the submicron level.…”

Section: Introductionmentioning

confidence: 99%

“…XRD can obtain statistical data, but it has low spatial resolution and lacks spatial location and orientation information. Defects are recognised by ECCI based on the difference of channelling contrasts 3–7 . The spatial resolution of ECCI is also poor (2–5 μm) 3 .…”

Section: Introductionmentioning

confidence: 99%

EBSD patterns simulating multilayer twins based on dynamical theory of electron diffraction

et al. 2023

Journal of Microscopy

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Electron backscatter diffraction (EBSD) can be employed to determine crystal structures but has not been used alone to identify defects at the atom scale due to the lack of understanding of the EBSD patterns generated by various structure defects. In the present work, the EBSD patterns of FCC‐Fe with 9‐layer, 6‐layer and 3‐layer twin structures are simulated, respectively, using the revised real space (RRS) method and compared with the counterpart of perfect crystals. Our results show that when the electron beam is incident along a direction parallel to the twin plane, the pattern appears symmetrical with respect to the corresponding Kikuchi band of the twin plane, and the diffraction details within the Kikuchi band also exhibit symmetry with respect to the middle line of the Kikuchi band. Moreover, the overall clarity of the patterns decreases, and the pattern becomes more blurred with increasing the distance from the Kikuchi band corresponding to the twin plane. By contrast, the incident electron beam along the direction perpendicular to the twin plane results in diffraction superposition of the matrix region and the shear region, which shows twofold rotational symmetry with respect to the Kikuchi pole corresponding to the normal to the twin plane. In addition, some extra Kikuchi bands appear in the EBSD patterns due to the long‐period structures of the multilayer twins. As the number of multilayer twins decreases, the number of extra Kikuchi bands decreases and the area of the blurring pattern increases. The correlation between twin structures and EBSD patterns provides theoretical insights for identifying twin structures by the EBSD technique.

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