2008
DOI: 10.1103/physreve.78.011605
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Growth directions of microstructures in directional solidification of crystalline materials

Abstract: In directional solidification, as the solidification velocity increases, the growth direction of cells or dendrites rotates from the direction of the thermal gradient to that of a preferred cristalline orientation. Meanwhile, their morphology varies with important implications for microsegregation. Here, we experimentally document the growth directions of these microstructures in a succinonitrile alloy in the whole accessible range of directions, velocities, and spacings. For this, we use a thin sample made of… Show more

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Cited by 85 publications
(64 citation statements)
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“…We attribute the origin of these different drifting regions to the 8 µm/s growth stage during which the high pulling rate leads to more dendritic patterns combined to a highly concave front. Those two elements lead to a tilting of the growth direction with respect to the pulling axis, possibly due to the combined effect of crystalline misorientations, as previously discussed [46,47], and thermal gradient misorientation at concave growth front [38,48]. A crystalline misorientation induces translational drift when the thermal gradient is aligned to the pulling axis but combined to the misorientation of the thermal gradient due to concavity, of axial symmetry, a complex variation of tilting of the growth direction throughout the pattern is observed.…”
Section: Iii25 Influence Of Pulling Velocity Historymentioning
confidence: 66%
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“…We attribute the origin of these different drifting regions to the 8 µm/s growth stage during which the high pulling rate leads to more dendritic patterns combined to a highly concave front. Those two elements lead to a tilting of the growth direction with respect to the pulling axis, possibly due to the combined effect of crystalline misorientations, as previously discussed [46,47], and thermal gradient misorientation at concave growth front [38,48]. A crystalline misorientation induces translational drift when the thermal gradient is aligned to the pulling axis but combined to the misorientation of the thermal gradient due to concavity, of axial symmetry, a complex variation of tilting of the growth direction throughout the pattern is observed.…”
Section: Iii25 Influence Of Pulling Velocity Historymentioning
confidence: 66%
“…We evidenced the critical influence of pattern drift on oscillation inhibition. Such a drift consists of a component of growth velocity in the plane normal to the pulling axis, which is due to a misalignment between the <100> preferred growth direction and the pulling/thermal axis; the direction and rate of drift depend on the misorientation angle and the pulling velocity [47].…”
Section: Discussionmentioning
confidence: 99%
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“…Another interesting feature of the solidification process is the growth direction of a microstructure [16][17][18][19][20]. It is well known that the growth directions of cells are approximately parallel to the thermal gradient direction, deflecting from the crystalline orientation <100> for a SCN-based alloy.…”
Section: Morphological Instability Near a Grain Boundarymentioning
confidence: 99%
“…6c and d. Because the inclined dendrites grow in the h100i direction with increasing arm spacing, [99][100][101][102] the UO dendrites move toward the FO dendrites. As a result, the competition between dendrites becomes intense at the GB, and the shape of the GB becomes zigzag as shown in Fig.…”
Section: Three-dimensional Simulation Of Competitive Growthmentioning
confidence: 99%