Peak Broadening Anisotropy and the Contrast Factor in Metal Alloys

Simm, Thomas H.

doi:10.3390/cryst8050212

Cited by 44 publications

(29 citation statements)

References 108 publications

(238 reference statements)

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“…The use of polycrystal plasticity models to predict diffraction peak broadening [4,14,28,29] is a less developed modelling route than for texture or lattice strains. In this method a polycrystal plasticity model is used to predict the activity of different slip systems in different grains, this is converted to broadening by an assumption on the relationship between slip activity and dislocation density.…”

Section: Powder Diffraction Measurementsmentioning

confidence: 99%

“…There are two main approaches that are generally followed: powder diffraction method and crystallographic texture measurements. In the former, plastic deformation can be quantified by measuring the changes in phase fraction [1], lattice strain [2], and the quantity and arrangement of dislocations [3][4][5]; whereas the latter gives information about changes in texture [6] of the alloy and orientations of individual phases. The two approaches provide complementary information about plastic deformation but require separate experimental set-ups.…”

Section: Introductionmentioning

confidence: 99%

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The τ-plot, a multicomponent 1-D pole figure plot, to quantify the heterogeneity of plastic deformation

Simm

Das

Forsey

et al. 2020

Materials Characterization

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An approach is presented that allows multi-scale characterisations of heterogeneous deformation in crystalline materials by employing a range of characterisation techniques including: electron backscatter diffraction, digital image correlation and neutron diffraction powder measurements. The approach will be used to obtain critical information about the variations in parameters that characterise the deformed state in different crystallographic orientation texture components of a sample in a statistically significant way. These parameters include lattice strains, texture evolution, peak broadening, dislocation density, planar faults, phase changes and surface strain. This approach allows verification of models of plastic deformation to provide a more detailed view of plastic deformation heterogeneity at multiple length scales than obtained by other characterisation approaches. The approach demonstrated here is applied to two stainless steel alloys; an alloy that exhibits phase transformation during deformation and an alloy that remains the same phase all through deformation process.

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Section: Powder Diffraction Measurementsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The τ-plot, a multicomponent 1-D pole figure plot, to quantify the heterogeneity of plastic deformation

Simm

Das

Forsey

et al. 2020

Materials Characterization

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show abstract

“…22) The measured full-widths at half maximum (FWHMs), asymmetric factors, and crystallite sizes of the PyC layers are listed Table 1. The asymmetric factors, which increase with the generation of stacking faults, 23) of P5 and P100 were calculated to be 1.27 and 1.4, respec-tively. With a decrease in FWHM values and asymmetric factors, defects like stacking faults also decrease.…”

Section: Microstructure Of the Pyc Layers Deposited On Carbon Preformsmentioning

confidence: 99%

Microstructural Control of Pyrolytic Carbon Layer Deposited from Methane by Isotropic Chemical Vapor Infiltration

Jeong

Choi

Yoon

2019

J. Korean Ceram. Soc

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Pyrolytic carbon (PyC) layers were deposited using methane. The PyC layer deposited with 5% methane showed highly textured graphite, while that deposited using 100% methane showed low textured graphite. The degrees of anisotropy of the carbon layers were measured using an X-ray diffractometer, a transmission electron microscope, and a Raman spectroscope, and the results were compared with those reported previously. The orientation angles obtained from the fast Fourier transformation of the high-resolution transmission electron microscopy images and the I D /I G intensity ratios obtained from the Raman spectra were used to evaluate the anisotropy of the PyC layers.

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“…Simm et al, have applied the line-profile analysis methods to investigate the dislocation character in FCC and hexagonal closed-packed alloys [26][27][28]. The results showed that heterogeneous microstructures were formed during plastic deformation in FCC nickel and stainless steel.…”

mentioning

confidence: 99%

Characterization of Dislocation Rearrangement in FCC Metals during Work Hardening Using X-ray Diffraction Line-Profile Analysis

Nakagawa

Hayashi

Takano-Satoh

et al. 2020

QuBS

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Multiplication and rearrangement of dislocations in face-centered cubic (FCC) metals during tensile deformation are affected by grain size, stacking fault energy (SFE), and solute elements. X-ray diffraction (XRD) line-profile analysis can evaluate the dislocation density (ρ) and dislocation arrangement (M) from the strength of the interaction between dislocations. However, the relationship between M and ρ has not been thoroughly addressed. In this study, multiplication and rearrangement of dislocations in FCC metals during tensile deformation was evaluated by XRD line-profile analysis. Furthermore, the effects of grain size, SFE, and solute elements on the extent of dislocation rearrangement were evaluated with varying M values during tensile deformation. M decreased as the dislocation density increased. By contrast, grain size and SFE did not exhibit a significant influence on the obtained M values. The influence of solute species and concentration of solute elements on M changes were also determined. In addition, the relationship between dislocation substructures and M for tensile deformed metals were also explained. Dislocations were loosely distributed at M > 1, and cell walls gradually formed by gathering dislocations at M < 1. While cell walls became thicker with decreasing M in metals with low stacking fault energy, thin cell walls with high dislocation density formed for an M value of 0.3 in metals with high stacking fault energy.

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Peak Broadening Anisotropy and the Contrast Factor in Metal Alloys

Cited by 44 publications

References 108 publications

The τ-plot, a multicomponent 1-D pole figure plot, to quantify the heterogeneity of plastic deformation

The τ-plot, a multicomponent 1-D pole figure plot, to quantify the heterogeneity of plastic deformation

Microstructural Control of Pyrolytic Carbon Layer Deposited from Methane by Isotropic Chemical Vapor Infiltration

Characterization of Dislocation Rearrangement in FCC Metals during Work Hardening Using X-ray Diffraction Line-Profile Analysis

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