Micromechanisms of grain refinement during extrusion of Mg-0.3 at.% Al at low homologous temperature

Coarse grained Mg–0.3 at.% Al (0.33 in wt.%) alloy was processed by direct extrusion with a reduction ratio of 25:1 at a temperature of ∼ 433 K. The extrusion remainder was removed from the die and analysed in three distinct zones: the cast billet, the conical zone of extrusion die, and the as-extru...

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Bibliographic Details
Published inMaterials characterization Vol. 93; pp. 102 - 109
Main Authors JÄGER, A, GÄRTNEROVA, V, MUKAI, T
Format Journal Article
LanguageEnglish
Published New York, NY Elsevier 01.07.2014
Subjects
ALLOYS
BACKSCATTERING
Cross-disciplinary physics: materials science; rheology
DEFORMATION
DISLOCATIONS
ELECTRON DIFFRACTION
Exact sciences and technology
EXTRUSION
GRAIN REFINEMENT
MAGNESIUM
MATERIALS SCIENCE
MICROSTRUCTURE
Phase diagrams and microstructures developed by solidification and solid-solid phase transformations
Physics
RECRYSTALLIZATION
Solidification
Grain size
Forming processes
Temperature
Bimodal structure
Electron diffraction
Dynamical recrystallization
Dynamic recrystallization
EBSD
Extrusion
Magnesium
Spinning
Microstructure
Grain refinement
Low temperature
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Summary:Coarse grained Mg–0.3 at.% Al (0.33 in wt.%) alloy was processed by direct extrusion with a reduction ratio of 25:1 at a temperature of ∼ 433 K. The extrusion remainder was removed from the die and analysed in three distinct zones: the cast billet, the conical zone of extrusion die, and the as-extruded rod. The zones were characterized by electron backscatter diffraction (EBSD) and light microscopy techniques to identify the processes responsible for grain refinement. Complex networks of (10–12) twins in practically all grains produced a noticeable microstructural fragmentation even before the material reached the conical zone of the die. Deformation twinning extended up to the entrance zone of the conical die where it was followed by a continuous dynamic recrystallization (CDRX) that gradually changed low angle boundaries to high angle boundaries. It is apparent that geometrically necessary dislocations play a crucial role in the formation of new grain boundaries. CDRX results in a bimodal structure with grain diameters ∼ 3 and ∼ 30 μm. As a material flows through the conical zone, the ratio of large to small grains is progressively decreased by CDRX in favour of fine grains. The as-extruded microstructure (a rod 8 mm in diameter), with an average grain diameter of ∼ 2.1 μm, shows a strong texture where the vast majority of grains (99.99%) have the c-axis oriented at least 30° from the extrusion direction. - Highlights: • Coarse grained Mg–0.3 at.% Al alloy was extruded at temperature of ∼ 433 K. • Processes responsible for grain refinement were analysed in extrusion remainder. • In the first stage, complex (10–12) twinning produced a noticeable fragmentation. • Deformation twinning was followed by continuous dynamic recrystallization. • 99.99% of grains in extruded rod have c-axis oriented > 30° from extrusion direction.
ISSN:1044-5803
1873-4189
DOI:10.1016/j.matchar.2014.03.023