X-ray line-broadening study of the dislocation cell structure in deformed [001]-orientated copper single crystals

Ungár, Tamás; Mughrabi, H.; Rönnpagel, D.; Wilkens, M.

doi:10.1016/0001-6160(84)90106-8

Cited by 316 publications

(160 citation statements)

References 26 publications

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“…Th is observation provides further direct evidence that fl uctuations are an inherent feature in deformed microstructures, in line with earlier work of others [9][10][11] . Finally, Levine and co-workers could also show that the average diff raction profi les, obtained from larger volumes of the same crystal, exhibit characteristic asymmetrically broadened line profi les, similar to the earlier observations 7,8 . All these facts confi rm that the principles of the composite model are correct.…”

supporting

confidence: 80%

“…Th e X-rays probe the lattice strains due to dislocations and, at the same time, the superimposed external and internal stresses. Th e results of early TEM observations and X-ray diff raction experiments on deformed single crystals of copper were consistent with the composite model 7,8 , and revealed the presence of long-range internal stresses within the cell structure of the crystals, as shown schematically in Fig. 1.…”

supporting

confidence: 73%

“…In particular, it could be shown that the X-ray-diff raction line profi les exhibited a characteristic asymmetric line broadening. It can be shown that this is a direct consequence of the presence of long-range internal stresses 7,8 . Nevertheless, some questions remained open, partly related to the fact that the results obtained in these earlier X-ray studies were not spatially resolved but represented average values from larger regions.…”

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Erratum: Anodes sliced with ions

Boukamp¹

2006

Nature Mater

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nature materials | VOL 5 | AUGUST 2006 | www.nature.com/naturematerials the platinum wire. Triangulation (a method that allows fi nding a position by combining three others) between the positions of the incident beam, the platinum wire and the shading of the diff racted image allows the identifi cation of the portion of specimen that produces the diff raction signal. In addition, the diff raction spots provide the local lattice spacing and lattice-spacing distribution. Th e spatial resolution is still far from what TEM provides routinely, but it is close to what can be achieved today [1][2][3][4][5]6 .Th e fundamentals of plastic deformation of crystals containing a dislocation cell structure were developed more than twenty years ago and are described in the so-called composite model 7 . Th e basic idea is that the cell-wall regions of high dislocation density are harder than the cell-interior regions of low dislocation density. Under the action of an externally applied stress, both cell walls and cell interiors are assumed to deform compatibly. Th e deformation induces internal stresses of the same sign as the external stress in the cell walls, and of opposite sign (or 'back') in the cell interiors. Th e X-rays probe the lattice strains due to dislocations and, at the same time, the superimposed external and internal stresses. Th e results of early TEM observations and X-ray diff raction experiments on deformed single crystals of copper were consistent with the composite model 7,8 , and revealed the presence of long-range internal stresses within the cell structure of the crystals, as shown schematically in Fig. 1. In particular, it could be shown that the X-ray-diff raction line profi les exhibited a characteristic asymmetric line broadening. It can be shown that this is a direct consequence of the presence of long-range internal stresses 7,8 . Nevertheless, some questions remained open, partly related to the fact that the results obtained in these earlier X-ray studies were not spatially resolved but represented average values from larger regions.Th e merit of the work by Levine and co-workers 5 lies in the fact that, in their X-ray-diff raction experiments, the diff racted signals are highly spatially resolved and in a one-to-one correlation with welldefi ned regions of submicrometre size in the cell interiors of the crystal. Th us, the authors could conclude from the shift s of the X-ray-diff raction profi les obtained from small local regions, that long-range internal back-stresses prevailed in the cell interiors of their specimens that had been deformed in tension or in compression. Moreover, the internal stresses could be assigned unambiguously to one particular cell-interior region from which the diff racted intensity came. Another interesting new feature of these fi ndings is that the magnitude of the internal back-stresses varied markedly from one cell interior to the next, indicating a signifi cant fl uctuation. Th is observation provides further direct evidence that fl uctuations are an inherent fea...

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confidence: 80%

supporting

confidence: 73%

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confidence: 99%

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Erratum: Anodes sliced with ions

Boukamp¹

2006

Nature Mater

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“…Other factors such as dislocation density, slip activity [32], and the presence of stacking faults can also affect the shape and/or position of diffraction peaks [27]. Warren [39], Randle and Engler [40] developed the XRDLPA approach for the analysis of the microstructure, which was later followed by others [28,[41][42][43][44][45] with some modifications making it possible to determine the crystallite size and microstrain in materials reliably. Similarly to [16,23], the modified Rietveld [46] method has been used in order to characterise microstructures in this investigation.…”

Section: Methods Of X-ray Diffraction Line Profile Analysismentioning

confidence: 99%

“…For materials containing two or more phases, it generally is more convenient to use XRD as the peaks of the constituent phases appear distinctly in the profile. Several XRDLPA investigations have been performed on steels [22][23][24][25][26], Cu [27][28][29] and Zr [30][31] alloys. In contrast, a fewer number of investigations using the XRDLPA have been performed on Ti alloys [32][33][34].…”

Section: Introductionmentioning

confidence: 99%

The effect of cooling rates on the microstructure and mechanical properties of thermo-mechanically processed Ti–Al–Mo–V–Cr–Fe alloys

Ahmed

Savvakin

Ивасишин

et al. 2013

Materials Science and Engineering: A

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The effect of cooling rates on the microstructure and mechanical properties of thermo-mechanically processed Ti-Al-Mo-V-Cr-Fe alloys AbstractTwo near-β titanium alloys, Ti-5Al-5Mo-5V-1Cr-1Fe and a modified one containing 2 wt% Cr (Ti-5Al-5Mo-5V-2Cr-1Fe) were produced from Ti hydride precursor powders via the cost-effective blended elemental powder metallurgy technique. The effects of two cooling rates (10 K s−1 and 1 K s−1) during thermo-mechanical processing on the microstructure and mechanical properties were investigated using X-ray diffraction and scanning electron microscopy. X-ray line profile analysis revealed that dislocation densities and microstrain in β-Ti phase are higher than in α-Ti phase for all cases. In both alloys, slower cooling results in an increase in α volume fraction and promotes morphology of continuous grain boundary α phase. A lower total elongation is obtained in both alloys under slower cooling which could be accounted for by the continuous morphology of α phase. Overall, Ti-5Al-5Mo-5V-1Cr-1Fe displays higher ultimate tensile strength and total elongation compared to Ti-5Al-5Mo-5V-2Cr-1Fe, regardless of the cooling rate. Two near-β titanium alloys, Ti-5Al-5Mo-5V-1Cr-1Fe and a modified one containing 2 wt. % Cr (Ti-5Al-5Mo-5V-2Cr-1Fe) were produced from Ti hydride precursor powders via the cost-effective blended elemental powder metallurgy technique. The effects of two cooling rates (10 Ks -1 and 1 Ks -1 ) during thermo-mechanical processing on the microstructure and mechanical properties were investigated using X-ray diffraction and scanning electron microscopy. X-ray line profile analysis revealed that dislocation densities and microstrain in β-Ti phase are higher than in α-Ti phase for all cases. In both alloys, slower cooling results in an increase in α volume fraction and promotes morphology of continuous grain boundary α phase. A lower total elongation is obtained in both alloys under slower cooling which could be accounted for by the continuous morphology of α phase. Overall, Ti-5Al-5Mo-5V-1Cr-1Fe displays higher ultimate tensile strength and total elongation compared to Ti-5Al-5Mo-5V-2Cr-1Fe, regardless of the cooling rate.

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