2015
DOI: 10.1016/j.matdes.2015.07.003
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Microstructure and mechanical properties of LA51 and LA51–0.5Y alloys with different accumulated strains and rolling temperatures

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Cited by 19 publications
(12 citation statements)
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“…"a," "b," and "d" introduce the ellipse's major and minor diameters and the initial circle diameter, respectively. indicated two independent slip systems and β-Li phase with BCC structure presents at least twelve autonomous slip systems at room temperature, so Mg alloys containing the BCC structure such as Mg-Li could have more ductility [8]. Also, it could be concluded that more elongation at room temperature that was occurred due to β-Li phase.…”
Section: Anisotropy and Formabilitymentioning
confidence: 94%
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“…"a," "b," and "d" introduce the ellipse's major and minor diameters and the initial circle diameter, respectively. indicated two independent slip systems and β-Li phase with BCC structure presents at least twelve autonomous slip systems at room temperature, so Mg alloys containing the BCC structure such as Mg-Li could have more ductility [8]. Also, it could be concluded that more elongation at room temperature that was occurred due to β-Li phase.…”
Section: Anisotropy and Formabilitymentioning
confidence: 94%
“…The α-Mg phase of the HCP structure precipitates in the matrix of the β-Li, which is of a body center cubic (BCC) structure [11,12]. Generally, for Mg LZ dual phase alloys, α-Mg phase with HCP structure indicates two independent slip systems and β-Li phase with BCC structure presents at least twelve autonomous slip systems at room temperature [8]. Therefore, it can be concluded that more deformation at room temperature occurs in β-Li phase because β-Li phase has a higher ductility and lower strength compared to α-Mg phase [13,14].…”
Section: Introductionmentioning
confidence: 99%
“…According to the research of Hanwu et al, 33 the rise of the strain rate causes the dual-phase Mg-Li alloys elongation and tensile strength decreased and increased, respectively. Also, the effect of rolling temperature and accumulated applied strain on the Mg LA51 and LA51 + 0.5Y alloys have been evaluated by Wang et al 34 which LA51 + 0.5Y showed more proper mechanical properties compared to LA51. Although several types of research were performed regarding the Mg-Li mechanical properties, 35 rolling process effects, 36 and fracture behavior, 37,38 fewer studies focused on the impact of the roll bonding process on these alloys.…”
Section: Introductionmentioning
confidence: 99%
“…Magnesium alloys are a hexagonal close-packed (HCP) structure, which leads to reduced formability in ambient temperature [3,[5][6][7]. Magnesium-Lithium alloy is one of the most favorable engineering metal due to its incredible properties, such as high formability and ultralow density [3,[8][9][10]. According to magnesium-lithium binary phase diagram, when the lithium quantity is higher than 5.7 wt.% and lower than 11 wt.% (between 5.7 and 11 wt.%), the microstructure is formed of the dual α-Mg + β-Li dual phase.…”
Section: Introductionmentioning
confidence: 99%