Case studies on the application of high-resolution electron channelling contrast imaging – investigation of defects and defect arrangements in metallic materials

Weidner, Anja; Biermann, Horst

doi:10.1080/14786435.2015.1006296

Cited by 28 publications

(13 citation statements)

References 100 publications

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“…Since the overall BSE signal is lower in the low-tilt configuration, in order to ensure adequate performance, it is necessary to operate a beam with small convergence angle and sufficient probe current, and to use a BSE detector with high collection efficiency. 25 This new configuration provided dislocation contrast characteristics comparable to those obtained by the high-tilt configuration. It is known that operational parameters can be adjusted to optimize BSE contrast.…”

Section: Electron Channeling Contrast Imaging (Ecci)supporting

confidence: 53%

“…At the beginning of the 1990s, for instance, ECCI was conducted with specimen tilt of »45 with respect to the incident electron beam, with a side-mounted BSE detector, as shown in Figure 2c under high-tilt configuration. 25 On the other hand, a low-tilt configuration, schematically described in Figure 2c, was used from the beginning of the 1980s, 133 e.g., for applications in geosciences, 135 and later by Simkin et al (1999). Sample tilting angles below 10 enabled the use of general-purpose pole piece-mounted backscatter detectors instead of specialized forward-scattered electron detectors, allowing access to more advantageous ECC imaging conditions.…”

Section: Electron Channeling Contrast Imaging (Ecci)mentioning

confidence: 99%

“…ECCI enables the analysis of large areas with good statistics, and facilitates easier implementation of in-situ studies compared to TEM. 25 An additional benefit of ECCI over TEM with regards to sample geometry is that in ECCI only one free surface needs to be exposed, as opposed to the two free surfaces required by TEM, which may cause significant relaxation of stresses.…”

Section: Electron Channeling Contrast Imaging (Ecci)mentioning

confidence: 99%

“…ECCI has been available for 50 years, but is currently being applied in larger extent in metallurgy due to recent technical developments that have simplified the analysis. [23][24][25] Moreover, the improved SEM performance together with the operation of ECCI in controlled diffraction condition, i.e., in combination with EBSD, has enabled high-resolution studies of nano-scale structures. 26,27 The application of EBSD, TKD, and ECCI for the characterization of metallic microstructures is likely to continue expanding.…”

Section: Introductionmentioning

confidence: 99%

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Recent Developments of Crystallographic Analysis Methods in the Scanning Electron Microscope for Applications in Metallurgy

Borrajo-Pelaez

Hedström

2017

Critical Reviews in Solid State and Materials Sciences

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The field of metallurgy has greatly benefited from the development of electron microscopy over the last two decades. Scanning electron microscopy (SEM) has become a powerful tool for the investigation of nano-and microstructures. This article reviews the complete set of tools for crystallographic analysis in the SEM, i.e., electron backscatter diffraction (EBSD), transmission Kikuchi diffraction (TKD), and electron channeling contrast imaging (ECCI). We describe recent relevant developments in electron microscopy, and discuss the state-of-the-art of the techniques and their use for analyses in metallurgy. EBSD orientation measurements provide better angular resolution than spot diffraction in TEM but slightly lower than Kikuchi diffraction in TEM, however, its statistical significance is superior to TEM techniques. Although spatial resolution is slightly lower than in TEM/ STEM techniques, EBSD is often a preferred tool for quantitative phase characterization in bulk metals. Moreover, EBSD enables the measurement of lattice strain/rotation at the sub-micron scale, and dislocation density. TKD enables the transmitted electron diffraction analysis of thin-foil specimens. The small interaction volume between the sample and the electron beam enhances considerably the spatial resolution as compared to EBSD, allowing the characterization of ultra-finegrained metals in the SEM. ECCI is a useful technique to image near-surface lattice defects without the necessity to expose two free surfaces as in TEM. Its relevant contributions to metallography include deformation characterization of metals, including defect visualization, and dislocation density measurements. EBSD and ECCI are mature techniques, still undergoing a continuous expansion in research and industry. Upcoming technical developments in electron sources and optics, as well as detector instrumentation and software, will likely push the border of performance in terms of spatial resolution and acquisition speed. The potential of TKD, combined with EDS, to provide crystallographic, chemical, and morphologic characterizations of nano-structured metals will surely be a valuable asset in metallurgy.

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Section: Electron Channeling Contrast Imaging (Ecci)supporting

confidence: 53%

Section: Electron Channeling Contrast Imaging (Ecci)mentioning

confidence: 99%

Section: Electron Channeling Contrast Imaging (Ecci)mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Recent Developments of Crystallographic Analysis Methods in the Scanning Electron Microscope for Applications in Metallurgy

Borrajo-Pelaez

Hedström

2017

Critical Reviews in Solid State and Materials Sciences

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“…Electron channeling contrast imaging (ECCI) is a powerful technique for observing and characterizing crystallographic defect such as dislocations, stacking faults, and grain boundaries in scanning electron microscopy (SEM) [17][18][19][20][21][22][23]. In order to detect defects, ECCI uses the fact that the backscattered electron yield is very sensitive to the angle between the incident beam and the crystal lattice.…”

Section: Introductionmentioning

confidence: 99%

Accurate electron channeling contrast analysis of a low angle sub-grain boundary

et al. 2015

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a b s t r a c tHigh resolution selected area channeling pattern (HR-SACP) assisted accurate electron channeling contrast imaging (A-ECCI) was used to unambiguously characterize the structure of a low angle grain boundary in an interstitial-free-steel. The boundary dislocations were characterized using TEM-style contrast analysis. The boundary was determined to be tilt in nature with a misorientation angle of 0.13°consistent with the HR-SACP measurements. The results were verified using high accuracy electron backscatter diffraction (EBSD), confirming the approach as a discriminating tool for assessing low angle boundaries.The development and structure of low angle grain boundaries play critical roles in a wide range of materials processes and behaviors. Examples of where such boundaries are inexorably linked to behavior include the development of low energy dislocation structures during static and dynamic recovery, creation of dislocation cell structures during fatigue deformation, and many creep processes.In order to fully understand many of these phenomena, it is necessary to characterize low angle boundaries in terms of their misorientations and dislocation structure. In many cases such studies have been carried out using transmission electron microscopy (TEM) in conjunction with electron diffraction, which offers direct imaging combined with high accuracy orientation measurements [1-9]. Nevertheless, TEM is limited by the need to create, and the potential artifacts of, thin foils [10,11].Over the past two decades electron backscattered diffraction (EBSD) and associated orientation mapping has been used to rapidly map crystal orientations at the surfaces of bulk materials, allowing sub grain structures to be readily observed over large areas [12,13]. However, this approach is limited in that it does not allow direct imaging and characterization of the defects associated with low angle boundaries and, in most cases, is hampered by the inherent limits in precision of the Hough transform based approach to solving EBSD patterns [14][15][16].Electron channeling contrast imaging (ECCI) is a powerful technique for observing and characterizing crystallographic defect such as dislocations, stacking faults, and grain boundaries in scanning electron microscopy (SEM) [17][18][19][20][21][22][23]. In order to detect defects, ECCI uses the fact that the backscattered electron yield is very sensitive to the angle between the incident beam and the crystal lattice. ECC can be optimized by controlling the channeling conditions to so called two-beam conditions, allowing the characterization of crystallographic planes responsible for the channeling effect and facilitating TEM-style contrast analysis [17,24,25].A novel approach to control the channeling conditions for performing ECCI with an accuracy of 0.04°has recently been developed. This approach is based on an innovative procedure for collecting high angular and spatial resolution (about 500 nm) selected area channeling patterns (HR-SACPs) on the GEMINI-type electron column [...

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Electron backscatter diffraction beyond the mainstream

Nolze

Hielscher

Winkelmann

2016

Crystal Research and Technology

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We present special applications of electron backscatter diffraction (EBSD) which aim to overcome some of the limitations of this technique as it is currently applied in the scanning electron microscope. We stress that the raw EBSD signal carries additional information which is useful beyond the conventional orientation determination. The background signal underlying the backscattered Kikuchi diffraction (BKD) patterns reflects the chemical composition and surface topography but also contains channeling-in information which is used for qualitative real-time orientation imaging using various backscattered electron signals. A significantly improved orientation precision can be achieved when dynamically simulated pattern are matched to the experimental BKD patterns. The breaking of Friedel's rule makes it possible to obtain orientation mappings with respect to the point-group symmetries. Finally, we discuss the determination of lattice parameters from individual BKD patterns. Subgrain structure in a single quartz grain. The increased noise level in the left map reflects the lower precision of a standard orientation determination using band detection by the Hough transform. The right map results from the same experimental raw data after orientation refinement using a pattern matching approach. The colors correspond an adapted inverse pole figure color key with a maximum angular deviation of about 2 • from the mean orientation.

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Case studies on the application of high-resolution electron channelling contrast imaging – investigation of defects and defect arrangements in metallic materials

Cited by 28 publications

References 100 publications

Recent Developments of Crystallographic Analysis Methods in the Scanning Electron Microscope for Applications in Metallurgy

Recent Developments of Crystallographic Analysis Methods in the Scanning Electron Microscope for Applications in Metallurgy

Accurate electron channeling contrast analysis of a low angle sub-grain boundary

Electron backscatter diffraction beyond the mainstream

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