The mechanism for the self-accommodation microstructure of α variants during phase transformation of the Zr-2.5Nb alloy

doi:10.1016/j.jmst.2024.11.013

Abstract

Abstract: Although variant selection during the phase transformation of zirconium (Zr) alloys has been studied extensively, studies on the formation mechanism of microstructural characteristics related to α variant selection remain limited. The formation mechanisms of the self-accommodation morphology and inter-variant boundary characteristics of α variants in homogenized Zr-2.5Nb alloy cooled by water quenching (WQ), furnace cooling (FC), and air cooling (AC) were systematically investigated from the perspective of local strain during phase transformation. The α variants exhibited triangular morphologies in both the WQ and AC samples, and a colony morphology in the FC sample. Further, there were five types of inter-variant boundaries: Type I <0 0 0 1>/10.53°, Type II <1 1 $ \overline{2}$ 0>/60°, Type III <$ \overline{1.377} $ $\overline{1}$ 2.377 0.359>/60.83°, Type IV <$ \overline{10}$ 5 5 $ \overline{3}$>/63.26°, and Type V <1 $ \overline{2.38}$ 1.38 0>/90°. The proportion of Type II is up to 98 % in the AC sample and 57.9 % in the WQ sample; the Type I was very low in all three samples; and a high proportion of the Type V was observed in the FC sample (23.6 %). The self-accommodation morphology of α variants is closely related to the equivalent strain (ε_VM) during the variant selection. Theoretical calculations indicated that, for a specific 2-variant combinations, there were always one or more 3-variant combinations with a lower ε_VM than the 2-variant combinations. A lower ε_VM contributes to the presence of 3-variant combinations, which forms a triangle morphology. The formation of inter-variant boundaries is determined by the type and frequency of variants as well as the ε_VM of the 2-variant combinations. The order of the mean values of ε_VM for the five types of boundaries was Type II (0.0757), Type III (0.0859), Type IV (0.1012), Type V (0.1112), and Type I (0.1307). That is, Type II is the easiest and Type I is the most difficult, which resulted in a very high fraction of Type II and a very low fraction of Type I in the WQ, AC, and FC samples. The presence of a high fraction of Type V in the FC sample was related to the type and fraction of each variant.

Key words: Zirconium alloy, Phase transformation, Variant selection, Microstructure, Equivalent strain

Guodong Song, Conghui Zhang, Yunchang Xin, Xinde Huang, Peidong Wu, Jun Zhou, Wenguang Zhu, Xuan Zhou. The mechanism for the self-accommodation microstructure of α variants during phase transformation of the Zr-2.5Nb alloy[J]. J. Mater. Sci. Technol., 2025, 224: 92-104.

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