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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

SOLIDIFICATION BEHAVIORS OF PROEUTECTIC AL3SC AND AL-AL3SC EUTECTIC IN HYPEREUTECTIC AL-SC UNDERCOOLED MELT

Aoke Jiang (10716237) 28 April 2021 (has links)
<p>The lack of a thorough understanding of the solidification behaviors of the proeutectic Al<sub>3</sub>Sc and the Al-Al<sub>3</sub>Sc eutectic in a hypereutectic Al-Sc alloy stimulates the present dissertation. The major findings for the single-phase growth of the proeutectic Al<sub>3</sub>Sc is summarized as follows: At a low cooling rate (~1 ºC·s<sup>-1</sup>), the proeutectic Al<sub>3</sub>Sc phase’s formation was governed by the lateral growth, exposing six flat {100} facets. At an intermediate cooling rate (~400 ºC·s<sup>-1</sup>), the proeutectic Al<sub>3</sub>Sc grew in a dendritic manner, with well-defined backbones extending in eight <111> directions and paraboloidal dendrite tips, although the dendrite tips and side-branches turned into faceted steps at a late growth stage,when the lateral growth prevailed. At a high cooling rate (~1000 ºC·s<sup>-1</sup>), the proeutectic Al<sub>3</sub>Sc primarily crystallized into an entirely seaweed-structured particle, which was composed of interior compact seaweeds and exterior fractal seaweeds. In order to verify the proposed dendritic and seaweed growth mechanisms for the proeutectic Al<sub>3</sub>Sc, various morphological stability criteria were used, and fair agreement between the observed and the estimated characteristic length scales was reached.</p><p>On the Al-Al<sub>3</sub>Sc eutectic side, it was found that a rod-typed Al<sub>3</sub>Sc eutectic phase prevalently existed in an as-cast hypereutectic Al-Sc alloy that solidified via both slow cooling in air (~1 ºC·s<sup>−1</sup>) and rapid cooling in a wedge-shaped copper mold (up to ~3000 ºC·s<sup>−1</sup>). Al-Al<sub>3</sub>Sc eutectic dendrites were identified within a narrow region near the edge of the wedge. The eutectic dendrites had an equiaxed dendritic contour and a rod eutectic structure inside. Quantitative assessments revealed that an interface undercooling of 48.2 ºC was required to form the eutectic dendrites, or in other words, to enter the coupled zone of the Al-Al<sub>3</sub>Sc phase diagram. Furthermore, a phenomenon of scientific interest was discussed: When crystallizing under a near-equilibrium condition, the eutectic Al<sub>3</sub>Sc phase formed a non-faceted morphology, in contradiction to its faceted nature. Based on the competitive growth criterion, it was deduced that the non-faceting of the eutectic Al<sub>3</sub>Sc phase essentially reduced the interface undercooling for the resultant regular eutectic, in comparison to an otherwise irregular eutectic that would contain a faceted eutectic Al<sub>3</sub>Sc phase.</p>

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