Microstructure and Mechanical Properties of Selective Laser Melted Al-2.51Mn-2.71Mg-0.55Sc-0.29Cu-0.31Zn Alloy Designed by Supersaturated Solid Solution

doi:10.1007/s40195-021-01290-6

Abstract

Abstract:

Selective laser melting (SLM) of aluminium alloys for lightweight application is arousing widespread interest, but the available alloy compositions are limited due to unsatisfactory mechanical performances. The rapid solidification of SLM provides a pathway to design a novel alloy composition with extended solubility. This strategy is demonstrated by an additively manufactured novel Al-2.51Mn-2.71Mg-0.55Sc-0.29Cu-0.31Zn alloy with the supersaturated solid solution in the present study. The microstructure of as-build sample is characterized with multi-modal grains with the fine equiaxed grain (FEG, ~ 800 nm) at molten pool boundaries, coarse equiaxed grain (CEG, ~ 2 μm) and columnar dendrites (CD, ~ 4 μm) inside the molten pool, which relates to the precipitations type and distribution. It is observable that Al₃(Sc, Zr) precipitation particles with the size of ~ 50 nm are dispersed in the FEG zone, while the interior of CEG shows no Al₃(Sc, Zr) particle which only exists at the CEG boundaries. Regardless of FEG, CEG or CD, the slender Al₆Mn precipitation with the length of ~ 500 nm is distributed along the grain boundaries. Meanwhile, a lot of vacancies and thickness fringes are detected in the FEG zone, which confirms the supersaturated solid solution in laser rapid solidification. The ultimate tensile strength and yield strength of the as-printed sample are ~ 380 MPa and ~ 330 MPa, respectively, with elongation ~ 14%, which increase to ~ 440 MPa and ~ 410 MPa with a reduction of elongation to ~ 9% after heat treatment.

Key words: Selective laser melting, Al-2.51Mn-2.71Mg-0.55Sc-0.29Cu-0.31Zn, Supersaturated solid solution, Microstructure, Mechanical property, Precipitation

Minbo Wang, Ruidi Li, Tiechui Yuan, Haiou Yang, Pengda Niu, Chao Chen. Microstructure and Mechanical Properties of Selective Laser Melted Al-2.51Mn-2.71Mg-0.55Sc-0.29Cu-0.31Zn Alloy Designed by Supersaturated Solid Solution[J]. Acta Metallurgica Sinica (English Letters), 2022, 35(3): 354-368.

Figures/Tables 18

Table 1 Chemical composition of raw Al-Mn-Mg-Sc alloy powder (wt%)

Mn	Mg	Sc	Zr	Si	Cu	Zn	Al
2.51	2.71	0.55	0.41	0.77	0.29	0.31	Balance

Fig. 1 Location of samples selected for the microstructure and tensile characterizations

Fig. 2 Microstructure of the Al-Mn-Mg-Sc alloy atomized powder: a OM image; b BSE image

Fig. 3 a XRD patterns of powder and SLM samples with building direction and scanning directions; b-e the amplification of XRD patterns

Fig. 4 OM images of the SLM Al-Mn-Mg-Sc samples with different laser energy densities: a, a1 Q = 58.3 J/mm3; b, b1 Q = 62.5 J/mm3; c, c1 Q = 66.7 J/mm3; d, d1 Q = 75 J/mm3; building direction: a-d; scanning direction: a1-d1

Fig. 5 BSE images of SLM Al-Mn-Mg-Sc samples (Q = 66.7 J/mm3): a, b building direction; c, d scanning direction

Fig. 6 OM images showing characteristic microstructures of SLM Al-Mn-Mg-Sc samples in building direction a, b and scanning direction c, d

Fig. 7 Tensile strength of the SLM and HT samples with various laser energy density: a calculated UTS, YS and ${\varepsilon }_{\mathrm{f}}$; b stress-strain curves during tensile test

Fig. 8 Inverse pole figure, kernel average misorientation of Al-Mn-Mg-Sc alloy (Q = 66.7 J/mm3): a, b IPF maps; c, d KAM maps; a, c building direction; b, d scanning direction

Fig. 9 Grain size distribution a, b and misorientation angle distribution c, d of SLM Al-Mn-Mg-Sc samples in building direction a, c and scanning direction (b, d)

Fig. 10 PFs showing the {100} crystallographic orientation of SLM Al-Mn-Mg-Sc samples in building direction a and scanning direction b; c standard (001) stereographic projectionFull size image

Fig. 11 ODF sections of φ = 0° in building direction a and scanning direction b; c position of typical texture components in the section of φ = 0°

Fig. 12 SEM image of building direction revealing a layered microstructure consisting of multiple grains: FEG, CEG and CDFull size image

Fig. 13 Morphologies of the different crystal structure in building direction: a, d FEG; b CD; c CEG; e contrast between FEG and CD; f contrast between FEG and CEG

Fig. 14 a High angle annular dark field (HAADF-TEM) image of FEG in building direction; b EDS mapping for Al, Mn, Mg, Si, Sc, Cu and Zn distributions

Fig. 15 TEM images of sample processed by SLM: a bright-field TEM image of the building direction; b SAED pattern from a, showing the diffraction patterns of phases

Fig. 16 BFTEM and HRTEM images of FEG zone in building direction: a high density dislocations in BFTEM; b, c detailed dislocation pile up group in HRTEM; d vacancies and thickness fringes in BFTEM; e, f detailed thickness fringes in HRTEM

Fig. 17 a HRTEM images of CEG zone showing the crystalline structure of precipitations in CEG zone; b matrix α-Al with FCC structure; c, f the transformation of α-Al matrix to Al3(Sc, Zr) particle; d, e Al3(Sc, Zr) particle with L12 structure

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