Enhanced Grain Refining Effect of Mg-Zr Master Alloy on Magnesium Alloys via a Synergistic Strategy Involving Heterogeneous Nucleation and Solute-Driven Growth Restriction

doi:10.1007/s40195-024-01719-8

Abstract

Abstract:

Zirconium (Zr) emerges as the most effective grain refiner for magnesium (Mg) alloys incorporating Zr. Typically, Zr is introduced in the form of an Mg-Zr master alloy. However, within Mg-Zr master alloys, Zr predominantly exists in a particle form, which tends to aggregate due to attractive van der Waals forces. The clustered Zr is prone to settling, thereby reducing its refining impact on Mg alloys. In this work, a combined pretreatment process for Mg-Zr master alloys was proposed, encompassing the introduction of a physical field to intervene the agglomeration of particle Zr and the employ of high-temperature dissolution and peritectic reactions to promote the solid solution of Zr. The results demonstrate that the particle Zr within the pretreated Mg-Zr master alloy is effectively dispersed and refined, and greater solute Zr levels can be achieved. The subsequent grain refinement ability was studied on a typical Mg-6Zn-0.6Zr (wt%) alloy. The outcome highlights that an improvement in the grain refinement efficacy (32.4%) of Mg-Zr master alloys was obtained with a holding time of 60 min. The pretreated Mg-Zr master alloy significantly augments the efficiency of grain refinement for Mg alloys through a synergistic strategy involving heterogeneous nucleation and solute-driven growth restriction. The crucial factor in achieving effective grain refinement of Zr in Mg alloys lies in regulating the presence and morphology of Zr in the Mg-Zr master alloy, distinguishing between particle Zr and solute Zr. This study introduces a novel method for developing more efficient Mg-Zr refiners.

Key words: Magnesium alloy, Mg-Zr master alloy, Grain refinement, Heterogeneous nucleation, Solute-driven growth restriction, Synergistic strategy

Gang Zeng, Hong Liu, Jing-Peng Xiong, Jian-Long Li, Yong Liu. Enhanced Grain Refining Effect of Mg-Zr Master Alloy on Magnesium Alloys via a Synergistic Strategy Involving Heterogeneous Nucleation and Solute-Driven Growth Restriction[J]. Acta Metallurgica Sinica (English Letters), 2024, 37(8): 1354-1366.

Figures/Tables 12

Fig. 1 Schematic illustration of the pre-treatment process for the Mg-Zr master alloy

Table 1 Composition of Mg-Zr master alloys (wt%)

Types of master alloy	Mg	Zr_T	Zr_S	Remarks
Master Alloy I	Bal.	30.1	0.25	As untreated
Master Alloy II	Bal.	15.3	0.48	As pretreated

Fig. 2 SEM micrographs a-f, proportion of clustered Zr g, and size distribution of particle Zr h of Mg-Zr master alloys. a Master Alloy I, b enlarged views of Region D in a, c Master Alloy II, d enlarged views of Region E in c, e enlarged views of Region F in d, f EDS surface scanning results of e

Fig. 3 a TEM morphology of Master Alloy II, b the enlarged view of Region A in a

Fig. 4 Microstructures of Mg-6Zn alloy and Mg-6Zn-0.6Zr alloy refined by various Mg-Zr master alloys

Fig. 5 Zr content a and grain size b of Mg-6Zn-0.6Zr alloys refined by various Mg-Zr master alloys at different holding time

Fig. 6 Zr nuclei in Mg–6Zn–0.6Zr alloys refined by different Mg–Zr master alloys: a SEM image of alloys refined by Master Alloy I; b enlarged views of the rectangular region in a; c right-field image of Zr nucleus in alloys refined by Master Alloy II; d HRTEM micrograph of the interface between α–Mg matrix and Zr nucleus (B = [2 $\overline{1 }\overline{1 } $ 0]Mg); e, f the corresponding selected area electron diffraction pattern (SADP) from α–Mg and the Zr particle, respectively

Fig. 7 DSC curve of Mg-6Zn-0.6Zr alloy refined by Master Alloy II

Table 2 Growth restriction factor (Q) of common solute elements in Mg alloys [27]

Zr	Ca	Si	Ni	Zn	Cu	Al	Sb	Mn
38.29	11.94	9.25	6.13	5.31	5.28	4.32	0.53	0.15

Fig. 8 Synergistic strategy of Zr on grain refinement of Mg alloy: a diagram of a typical columnar grain structure of Mg-6Zn alloys without Zr; b diagram of the synergistic grain-refining strategy including heterogeneous nucleation and solute-driven growth restriction

Fig. 9 Effect of melt temperature and Zr particle size on settling speed: a effect of melt temperature, assume the particle diameter is 1 mm; b effect of Zr particle size, assume the melt temperature is 720 ℃

Fig. 10 Comparison of grain refinement efficiency of Mg-Zr master alloys treated by various methods. The holding time of 0 min indicates that the melt is added with Mg-Zr master alloy and poured immediately after stirring. (UHFR-TIGR: tungsten inert gas arc re-melting with ultra-high frequency pulses; FSP: friction stir processing; ECAE: equal channel angular extrusion)

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