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Grain boundary structure and deformation defects in nanostructured Al-Mg alloys processed by high pressure torsion. / Man, Ping Liu; Roven, Hans J.; Ungár, Tamas; Balogh, Levente; Murashkin, Maxim; Valiev, Ruslan Z.

In: Materials Science Forum, Vol. 584-586 PART 1, 01.01.2008, p. 528-534.

Research output: Contribution to journalArticlepeer-review

Harvard

Man, PL, Roven, HJ, Ungár, T, Balogh, L, Murashkin, M & Valiev, RZ 2008, 'Grain boundary structure and deformation defects in nanostructured Al-Mg alloys processed by high pressure torsion', Materials Science Forum, vol. 584-586 PART 1, pp. 528-534.

APA

Man, P. L., Roven, H. J., Ungár, T., Balogh, L., Murashkin, M., & Valiev, R. Z. (2008). Grain boundary structure and deformation defects in nanostructured Al-Mg alloys processed by high pressure torsion. Materials Science Forum, 584-586 PART 1, 528-534.

Vancouver

Man PL, Roven HJ, Ungár T, Balogh L, Murashkin M, Valiev RZ. Grain boundary structure and deformation defects in nanostructured Al-Mg alloys processed by high pressure torsion. Materials Science Forum. 2008 Jan 1;584-586 PART 1:528-534.

Author

Man, Ping Liu ; Roven, Hans J. ; Ungár, Tamas ; Balogh, Levente ; Murashkin, Maxim ; Valiev, Ruslan Z. / Grain boundary structure and deformation defects in nanostructured Al-Mg alloys processed by high pressure torsion. In: Materials Science Forum. 2008 ; Vol. 584-586 PART 1. pp. 528-534.

BibTeX

@article{c565ee095da84994b92bafa0e2de6392,
title = "Grain boundary structure and deformation defects in nanostructured Al-Mg alloys processed by high pressure torsion",
abstract = "An Al-0.5 Mg alloy and a commercial AA5182 alloy were subjected to high pressure torsion (HPT) to five turns under pressure of 6 GPa at room temperature. The grain boundary structure and deformation defects were investigated after HPT using high-resolution transmission electron microscopy (HRTEM). Low-angle, high-angle, equilibrium and non-equilibrium grain/subgrain boundaries, twin boundaries, full dislocations, dipoles, microtwins and stacking faults were identified by HRTEM. Extrinsic 60° dislocations in the form of dipoles were frequently observed in non-equilibrium grain/subgrain boundaries. In addition subgrain size distributions and dislocation densities were quantified by x-ray line profile analysis. It was observed that the average grain size decreased from about 120 nm to 55 nm as the Mg content increased from 0.5 to 4.1 wt%. Concomitantly the average stored dislocation density increased from 1.7 to 12.8 × 1014 m-2. Based on the HRTEM investigations and the x-ray line profile analyses, the deformation mechanism associated with the typical grain boundaries and deformation defects in the aluminium alloys were discussed.",
keywords = "Aluminium alloys, Deformation defects, Grain boundary structure, High pressure torsion, Non-equilibrium grain boundaries, Severe plastic deformation",
author = "Man, {Ping Liu} and Roven, {Hans J.} and Tamas Ung{\'a}r and Levente Balogh and Maxim Murashkin and Valiev, {Ruslan Z.}",
year = "2008",
month = jan,
day = "1",
language = "English",
volume = "584-586 PART 1",
pages = "528--534",
journal = "Materials Science Forum",
issn = "0255-5476",
publisher = "Trans Tech Publications Ltd",

}

RIS

TY - JOUR

T1 - Grain boundary structure and deformation defects in nanostructured Al-Mg alloys processed by high pressure torsion

AU - Man, Ping Liu

AU - Roven, Hans J.

AU - Ungár, Tamas

AU - Balogh, Levente

AU - Murashkin, Maxim

AU - Valiev, Ruslan Z.

PY - 2008/1/1

Y1 - 2008/1/1

N2 - An Al-0.5 Mg alloy and a commercial AA5182 alloy were subjected to high pressure torsion (HPT) to five turns under pressure of 6 GPa at room temperature. The grain boundary structure and deformation defects were investigated after HPT using high-resolution transmission electron microscopy (HRTEM). Low-angle, high-angle, equilibrium and non-equilibrium grain/subgrain boundaries, twin boundaries, full dislocations, dipoles, microtwins and stacking faults were identified by HRTEM. Extrinsic 60° dislocations in the form of dipoles were frequently observed in non-equilibrium grain/subgrain boundaries. In addition subgrain size distributions and dislocation densities were quantified by x-ray line profile analysis. It was observed that the average grain size decreased from about 120 nm to 55 nm as the Mg content increased from 0.5 to 4.1 wt%. Concomitantly the average stored dislocation density increased from 1.7 to 12.8 × 1014 m-2. Based on the HRTEM investigations and the x-ray line profile analyses, the deformation mechanism associated with the typical grain boundaries and deformation defects in the aluminium alloys were discussed.

AB - An Al-0.5 Mg alloy and a commercial AA5182 alloy were subjected to high pressure torsion (HPT) to five turns under pressure of 6 GPa at room temperature. The grain boundary structure and deformation defects were investigated after HPT using high-resolution transmission electron microscopy (HRTEM). Low-angle, high-angle, equilibrium and non-equilibrium grain/subgrain boundaries, twin boundaries, full dislocations, dipoles, microtwins and stacking faults were identified by HRTEM. Extrinsic 60° dislocations in the form of dipoles were frequently observed in non-equilibrium grain/subgrain boundaries. In addition subgrain size distributions and dislocation densities were quantified by x-ray line profile analysis. It was observed that the average grain size decreased from about 120 nm to 55 nm as the Mg content increased from 0.5 to 4.1 wt%. Concomitantly the average stored dislocation density increased from 1.7 to 12.8 × 1014 m-2. Based on the HRTEM investigations and the x-ray line profile analyses, the deformation mechanism associated with the typical grain boundaries and deformation defects in the aluminium alloys were discussed.

KW - Aluminium alloys

KW - Deformation defects

KW - Grain boundary structure

KW - High pressure torsion

KW - Non-equilibrium grain boundaries

KW - Severe plastic deformation

UR - http://www.scopus.com/inward/record.url?scp=56349172233&partnerID=8YFLogxK

M3 - Article

AN - SCOPUS:56349172233

VL - 584-586 PART 1

SP - 528

EP - 534

JO - Materials Science Forum

JF - Materials Science Forum

SN - 0255-5476

ER -

ID: 106660873