Revealing the Diversity of Dendritic Morphology Evolution During Solidification of Magnesium Alloys using Synchrotron X-ray Imaging: A Review

doi:10.1007/s40195-021-01319-w

Abstract

Abstract:

In this paper, the diversity of complicated dendrite microstructure and its evolution behavior during solidification in different magnesium alloys under various processing conditions were illustrated using synchrotron X-ray imaging technique. A variety of dendritic morphologies and branching structures were revealed, i.e., sixfold plate-like symmetric structure in Mg-Al-based structure, 12-branch structure in Mg-Zn-based alloys and 18-branch structure in Mg-Sn- and Mg-Ca-based alloys as well as seaweed like hyper-branched structure in Mg-38wt%Zn alloy. In addition, a dendrite morphology and orientation transition with increasing addition of Zn content were also observed in Mg-Zn alloy, with dendrite growth pattern transform from anisotropy (low Zn addition) with sixfold symmetric snow-flake structure to relative isotropy (intermediate Zn addition) where seaweed morphology presented and then back to anisotropy (high Zn addition) when only 12 branches with preferred < $11\overline{2}1$ > orientations were observed. The phase-field model representing the typical dendritic morphologies and branching structures under various conditions was also depicted and discussed. Further, the two-dimensional (2D) real-time dendrite growth dynamics in different Mg-based alloys captured using synchrotron X-ray radiography for unveiling the originate of the α-Mg dendrite was reviewed. Following this, the four-dimensional (3D + time) synchrotron X-ray tomographic in situ observation of dendritic morphology evolution indicating the formation mechanism of the diverse dendritic morphology during Mg-Sn- and Mg-Zn-based alloys was also summarized. Finally, the future study on exploring the complicated dendritic morphologies and their origination during solidification of Mg-based alloys is prospected.

Key words: Magnesium alloys, Solidification microstructure, Dendritic morphology, Synchrotron X-ray imaging, Growth pattern

Yanan Wang, Sansan Shuai, Chenglin Huang, Tao Jing, Chaoyue Chen, Tao Hu, Jiang Wang, Zhongming Ren. Revealing the Diversity of Dendritic Morphology Evolution During Solidification of Magnesium Alloys using Synchrotron X-ray Imaging: A Review[J]. Acta Metallurgica Sinica (English Letters), 2022, 35(2): 177-200.

Figures/Tables 26

Fig. 1 a Schematic diagram of X-ray imaging; b schematic diagram of X-ray tomography setup [32]

Fig. 2 Dendritic structure diagram of magnesium alloys obtained by traditional metallographic technique: a Mg-10wt%Zn alloys; b Mg-9Al-0.7Zn alloys

Fig. 3 Reconstructed 3D α-Mg dendrite morphology with 2D livewire algorithm from X-ray tomography a 2D slice; b reconstructed 3D result [33]

Fig. 4 a A reconstructed morphological image of α-Mg dendrite and its growth directions; b, c 3D reconstructed dendrites exactly validate branched structure analysis of a [34]

Fig. 5 Dendritic morphologies of binary magnesium alloys: a Mg-Al alloys [36]; b Mg-Zn alloys [13]; c Mg-Sn alloys [13]

Fig. 6 Whole polycrystalline morphologies of phase-field simulations using alternative preferred orientation [13]

Fig. 7 3D dendritic morphologies in equiaxed growth Mg-30wt% Sn a, b and Mg-30wt% Gd c, d alloys. e and f one dendrite of Mg-30wt% Sn viewed from different perspectives [37]

Fig. 8 Comparison of the dendrite morphology between a phase-field simulation and b X-tomography experiment. Dendrite morphologies view from < 0001 >, < $11\overline{2}0$ >, < $10\overline{1}0$ > and < $11\overline{2}3$ > direction where c-f for simulation and g-j for experiment, respectively [37]

Fig. 9 Dendritic morphology and branching structure in equiaxed solidified Mg-9wt%Ca alloy: a, b dendrites morphology of α-Mg along with the particle clusters (MgO) as nucleation site in equiaxed solidification condition: a 2D slice; b 3D rendering; c-e three types of secondary dendrite growth patterns of α-Mg; dendrites with 5, 4 and 3 branching arms are observed in equiaxed solidification condition; f-h proposed branching structure of primary arms in c-e, respectively [38]

Fig. 10 3D dendritic morphologies and branching mechanism of α-Mg dendrites in Mg-Zn alloys with various additions of Zn; Sect. 1 and Sect. 2 are supposed to be the basal plane and prismatic central plane, respectively. a, a1, a2 Mg-10wt%Zn; b, b1, b2 Mg-25wt%Zn; c, c1, c2 Mg-38wt%Zn; d, d1, d2 Mg-50wt%Zn. a1, a2, b1, b2, c1, c2, d1, d2 share the same scale bar, respectively [14]

Fig. 11 Conclusive figure summary of growth mode of magnesium alloy

Fig. 12 Growth pattern of the α-Mg dendrite in Mg-10wt%Ba alloy. a 2D slice images from synchrotron X-ray tomography experiments, where the primary phase (i.e., α-Mg dendrite) is in dark gray; b the reconstructed morphology of α-Mg dendrite, c the entire 3D growth pattern of the α-Mg dendrite, d relevant sections used to cut the α-Mg dendrite, where P0 is the cross section (i.e., the {0001} basal plane), while P1, P2 and P3 are the longitudinal sections that perpendicular to P0 with the angles between the three longitudinal sections being 60° (i.e., the { $10\overline{1}0$ } non-basal plane), e-h show the corresponding 2D sections of this α-Mg dendrite by P0, P1, P2 and P3 planes, respectively [45]

Fig. 13 Geometrical model describing the 3D growth pattern and outer contour shape of the α-Mg dendrite with hcp lattice structure. a Crystallographic planes related to the growth behavior of the α-Mg dendrite, b relevant crystallographic orientations within the basal plane, c final outer profile composed of those energetically favorable planes with lower surface energy predicted by the ab initio calculations, d outer contour of the ideal shape derived from surface energy and related crystalline anisotropy, e schematic of the 3D growth pattern with eighteen-primary-branches [45]

Fig. 14 Phase-field simulation showing the evolution of an eighteen-branched α-Mg dendrite at different time steps: a 5000, b 10,000, c 15,000, d 20,000, e 25,000, f 30,000 [46]

Fig. 15 Microstructural evolution of Mg-6wt%Gd alloy under different cooling rates: a R = 0.033 K/s, b R = 0.1 K/s and c R = 0.25 K/s at different time, where t0 is the beginning time of solidification [21]

Fig. 16 taken from X-ray radiograms showing the time evolution of the α-Mg primary phase in the Elektron 21 alloy under nearly isothermal conditions at T = 0.0125 K/s [54]

Fig. 17 2D radiograph of microstructure development during AZ91 solidification at a cooling rate of 0.083 K/s [55]

Fig. 18 Two types’ morphology of dendrites in Mg-Gd alloys: a sixfold equiaxed structure, b butterflied structure [56]

Fig. 19 Floating, collision and rotation of dendrites in Mg-Gd alloys when the cooling rate is at about 0.033 K/s under the fixed temperature gradient [56]

Fig. 20 Dendritic morphology of Mg-6wt%Gd alloy of under three different cooling rates R = 0.033 K/s, R = 0.1 K/s and R = 0.25 K/s in directional solidification from the top to bottom, respectively: experimental results a1-a3, simulated results b1-b3 [57]

Fig. 21 2D slices and 3D surface rendering of equiaxed dendrite evolution during solidification of Mg-15wt% Sn for the cooling rates of 3 °C /min a1-a5, b1-b5 12 °C/min c1-c5, d1-d4 [32]

Fig. 22 3D dendritic morphology evolution for Mg-25wt%Zn a1-a4, Mg-38wt%Zn b1-b4 Mg-50wt%Zn c1-c4 alloys [59]

Fig. 23 a Volume normalized specific surface area (Sv) and solid volume fraction (fs) evolution of α-Mg dendrite with time during solidification; b average dendrite tip velocity in the mushy zone as a function of solidification time for Mg-25/38/50wt%Zn alloys; c measured evolution of solid fraction; d specific surface area evolution as a function of solid fraction, and fitted curves using modified Rath and Cahn’s model [32], [59]

Fig. 24 Images showing the evolution of dendritic structures of Mg-25wt%Zn a-1, a-2, b-1, b-2 Mg-38wt%Zn c-1, c-2, d-1, d-2 alloys before (time = 0 s) a-1, b-1, c-1, d-1 after a-2, b-2, c-2, d-2 the isothermal hold stage for coarsening [61]

Fig. 25 Microstructural evolution during solidification of a Mg-25Zn-7Al alloy and a Mg-25 Zn-7Al/SiC nanocomposite material [62]

Fig. 26 Images showing the 3D dendritic evolution of NP-free a-c, g-i NP Mg-25Zn-7Al d-f, j-l alloy [63]

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