The Role of Grain Boundary Sliding in Microstructural Evolution during Superplastic Deformation of a 7055 Aluminum Alloy

Kaibyshev, Rustam; Goloborodko, Alexandre; Musin, Fanil; Nikulin, Ilya; Sakai, Taku

doi:10.2320/matertrans.43.2408

Cited by 35 publications

(18 citation statements)

References 25 publications

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“…It is shown that the superplastic behavior of aluminum alloys in the unrecrystallized structure could be attributed to grain boundary sliding along high-angle grain boundaries. This grain boundary sliding along separate high-angle grain boundaries induces rotation in subgrains and facilitates transformation of low-angle grain boundaries to high-angle grain boundaries [25]. Therefore, uniform subgrain structure seems to provide enhanced grain boundary sliding and further transformation of low-angle grain boundaries to high-angle grain boundaries which leads to achieving higher elongations than banded subgrain structure.…”

Section: Resultsmentioning

confidence: 97%

Feasibility of attaining uniform grain structure and enhanced ductility in aluminum alloy by employing a beveled punch in equal-channel angular pressing

Nejadseyfi

Shokuhfar

Sadeghi

2016

Materials Science and Engineering: A

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Section: Resultsmentioning

confidence: 97%

Feasibility of attaining uniform grain structure and enhanced ductility in aluminum alloy by employing a beveled punch in equal-channel angular pressing

Nejadseyfi

Shokuhfar

Sadeghi

2016

Materials Science and Engineering: A

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“…This is related to the fact that the HABs can efficiently absorb the dynamically generated dislocations [30,31]. The simulation of microstructural evolution during CDRX has denoted that at such large strains the dynamic recovery alone is unable to justify the restoration of microstructure [13] and that misorientations are mainly increased by grain boundary sliding [32]. The latter analogy may be held for SPD of magnesium alloys to very large strain at such a high temperatures (330 C).…”

Section: Resultsmentioning

confidence: 96%

EBSD characterization of repetitive grain refinement in AZ31 magnesium alloy

Fatemi-Varzaneh

Zarei-Hanzaki

Cabrera

et al. 2015

Materials Chemistry and Physics

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“…When the feed rate is 0. 5 mm, 1 mm and 1.5 mm, the minimum grain size is 0.75 µm, 0.83 µm and 0.67 µm at low temperature, respectively; and the minimum grain size is 0.54 µm, 0.75 µm and 0.55 µm at the high temperature environment, respectively [11]. At the same feed rate, the dislocation density at low temperature is higher than that of high temperature, and the grain size at low temperature is higher than that of high temperature too.…”

Section: Resultsmentioning

confidence: 99%

A Study on Microstructure Evolution of 7055 Aluminum Alloy Based Under Extreme Environment

Zhang¹,

Li²,

Wang³

2017

Adv Automob Eng

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In order to fill the mechanism of microstructure evolution and corrosion resistance of 7055 aluminum alloy in extreme environment, the 7055 aluminum alloy Which was subjected to T6I4 heat treatment was selected as the research object. High speed machining experiments were performed at low temperature (-60°C) and high temperature (350°C). The dislocation density, grain size, TEM microstructure and corrosion resistance of the cutting layer of 7055 aluminum alloy were investigated at low temperature (-60°C) and high temperature (350°C). The experimental results show that the dislocation density at low temperature is higher than that at high temperature under the same cutting speed and feed rate, and the grain size at low temperature is higher than that at high temperature too. In the low temperature environment, the continuous of the grain boundary is enhanced with the cutting speed increases, and the precipitation phase in the crystal is reduced and the precipitation phase on the grain boundary is obviously increased. Under the high temperature environment, with the increasing cutting speed, the degree of fibrosis of the grains is weakened and the dynamic recrystallization is obviously enhanced. Microstructures show significant dynamic recrystallization after high temperature cutting. And when the feed rate is 0.05 mm, the microstructure of 7055 aluminum alloy exists part of the sub-crystal; The larger the feed amount, the finer and longer the fibrous grains of the metallographic structure of cutting layer metal of 7055 aluminum alloy. There is a lot of dislocations in the cutting layer of 7055 aluminum alloy in low temperature environment. The higher the cutting speed, the smaller the dislocation density. No dislocations were found in the microstructure of the 7055 aluminum alloy cutting layer in the high temperature environment,and, the higher the cutting speed is, the less the number of precipitated phases is, and the GP region and η 'phase were transformed into η phase.

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The Role of Grain Boundary Sliding in Microstructural Evolution during Superplastic Deformation of a 7055 Aluminum Alloy

Cited by 35 publications

References 25 publications

Feasibility of attaining uniform grain structure and enhanced ductility in aluminum alloy by employing a beveled punch in equal-channel angular pressing

Feasibility of attaining uniform grain structure and enhanced ductility in aluminum alloy by employing a beveled punch in equal-channel angular pressing

EBSD characterization of repetitive grain refinement in AZ31 magnesium alloy

A Study on Microstructure Evolution of 7055 Aluminum Alloy Based Under Extreme Environment

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