Microstructural evolution, dislocation density and tensile properties of Al-6.5Si-2.1Cu-0.35Mg alloy produced by different casting processes

doi:10.1016/j.jmst.2021.02.074

Abstract

Abstract:

Al-Si-Cu-Mg foundry alloys are used in casting process technologies. However, their strength properties remain low due to their microstructural characteristics and porosity. In this work, the microstructural characteristics, dislocation densities, and mechanical properties of Al-Si-Cu-Mg cast alloys prepared through different casting methods were studied experimentally. Four casting processes, namely, gravity casting (GC), rheocasting (RC), thixoforming (Thixo), and Thixo with heat treatment, were used. The GC and RC samples had mainly dendritic α-Al phase microstructures and exhibited coarse Si particles and intermetallic compounds in their interdendritic regions. By contrast, the Thixo and heat-treated Thixo (HT-Thixo) samples exhibited microstructural refinement with uniformly distributed α-Al globules, fine fibrous Si particles, and fragmented intermetallic compounds among α-Al globules. The accumulation of dislocation densities increased in the Thixo sample as the strain was increased due to plastic deformation. Furthermore, the ultimate tensile strength and yield strength of the HT-Thixo sample increased by 87% and 63%, respectively, relative to those of the GC sample. The cleavage fracture displayed by the GC and RC samples led to brittle failure. Meanwhile, the Thixo and HT-Thixo samples presented dimple-based ductile fracture.

Key words: Al-Si-Cu-Mg alloy, Thixoforming, Microstructure, Mechanical property, Dislocation density

S. Samat, M.Z. Omar, A.H. Baghdadi, I.F. Mohamed, A. Rajabi, A.M. Aziz. Microstructural evolution, dislocation density and tensile properties of Al-6.5Si-2.1Cu-0.35Mg alloy produced by different casting processes[J]. J. Mater. Sci. Technol., 2021, 95: 145-157.

Figures/Tables 20

Table 1 Chemical composition of BM used in this study (wt.%).

Si	Mg	Cu	Fe	Mn	Al
6.50	0.35	2.1	0.32	0.12	Bal.

Fig. 1. Schematic of different casting processes: (a) GC, (b) RC, (c) Thixo.

Fig. 2. DSC heating flow and liquid fraction curves of the Al-Si-Cu-Mg alloys.

Fig. 3. Schematic of the tensile test specimen.

Fig. 4. Microstructures of Al-Si-Cu-Mg alloys produced through GC (a), RC (b), Thixo (c) and HT-Thixo (d).

Fig. 5. High-magnification OM images of Al-Si-Cu-Mg alloys produced through GC (a), RC (b), Thixo (c) and HT-Thixo (d).

Table 2 EDS point analysis results for the intermetallic compounds (wt%) of Al-Si-Cu-Mg alloy in Fig. 5.

Element	GC	RC	Thixo	HT-Thixo	Intermetallic compound
Al	65.4	71.4	74.3	83.7	Al₂Cu
Cu	34.6	28.6	25.7	16.3	Al₂Cu
Al	55.9	56.8	64.8	69.4	β-Al₅FeSi
Fe	26.1	22.1	21.8	20.4
Si	18.0	21.1	12.7	10.2
Al	50.2	53.6	55.1	62.4	Al₅Cu₂Mg₈Si₆
Cu	37.4	34.8	35.8	31.1
Mg	10.3	9.2	5.3	4.0
Si	2.1	2.4	3.9	2.6

Fig. 6. EDS mapping analysis of Thixo sample elements: (a) Si, (b) Cu, (c) Mg, (d) Fe, (e) Mn.

Fig. 7. EDS mapping analysis of HT-Thixo sample elements: (a) Si, (b) Cu, (c) Mg, (d) Fe, (e) Mn.

Fig. 8. Schematic of α-Al features and Fe intermetallic (a) and Si particles (b).

Table 3 Quantitative metallographic assessment of the microstructural features of GC, RC, Thixo, and HT-Thixo Al-Si-Cu-Mg alloys.

Sample	α-Al		Silicon Particle		Intermetallic
Sample	SF	GS (µm)	D (µm)	AR	Length (µm)
GC	N/A	N/A	13.5 ± 1.3	3.1	60 ± 4
RC	0.85 ± 0.08	43 ± 4	3.8 ± 0.3	2.2	22 ± 3
Thixo	0.82 ± 0.07	57 ± 4	3.5 ± 0.4	2.1	10 ± 3
HT-Thixo	0.84 ± 0.06	58 ± 2	2.2 ± 0.1	1.3	3 ± 2

Table 4 Hardness values of GC, RC, Thixo, and HT-Thixo Al-Si-Cu-Mg alloys.

Sample	GC	RC	Thixo	HT-Thixo
Hardness (HV)	93 ± 2	95 ± 3	100 ± 2	124 ± 2

Fig. 9. Stress-strain diagrams of GC, RC, Thixo, and HT-Thixo Al-Si-Cu-Mg alloys.

Fig 10. Tensile strength properties of GC, RC, Thixo, and HT-Thixo Al-Si-Cu-Mg alloys.

Fig 11. FE-SEM images of Al2Cu particle at grain boundaries: (a) Thixo sample, HT-Thixo sample.

Fig. 12. XRD patterns of AC, RC, Thixo, and HT-Thixo Al-Si-Cu-Mg alloys.

Fig. 13. Crystallite sizes and microstrains of Al-Si-Cu-Mg alloys produced through different casting processes based on the Williamson-Hall method.

Fig. 14. Determination of the lattice parameters of Al-Si-Cu-Mg alloys fabricated through different casting processes based on the Nelson-Riley method.

Table 5 Dislocation density of GC, RC, Thixo, and HT-Thixo Al-Si-Cu-Mg alloys.

Sample	d (nm)	ε (%)	a (Nelson-Riley Method) (Å)	b (10^-10 m)	ρ × 10¹⁴ (m ^{- 2})
GC	231.15	0.22	4.0391	2.856075000	1.15438
RC	92.46	0.26	4.0502	2.863923885	3.40133
Thixo	69.34	0.30	4.0522	2.865338099	5.23061
HT-Thixo	66.00	0.28	4.0523	2.865408809	5.12883

Fig. 15. SEM fractographs showing the fracture surfaces of GC (a), RC (b), Thixo (c) and HT-Thixo (d) alloys.

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