Evolution of the heat-resistant phases and deformation behavior of α-Al matrix of four alloys have been characterized by SEM and EBSD. The strengthening mechanisms influenced by morphology and distribution of the heat-resistant phases were described. And the strain contouring of the α-Al matrix after deformation was rendered. The heat-resistant phases with block-like as reticular or semi-reticular network distribution exist in grain boundary can effectively provide elevated-temperature strength for alloys, while the strain contouring of α-Al matrix is mainly concentrated in the area with fewer intermetallic phases. It is shown that intermetallic phase evolution corresponds to extrusion treatment and the formation of eutectic Si and primary Si, highly interconnected networks of intermetallic phases exist in the alloy in which the primary Si and the eutectic Si are simultaneously present or disappeared. And only the disappearance of the primary Si and the extrusion treatment will destroy the network structure of the intermetallic phases. A reticular or semi-reticular microstructure is more capable of matching strength and plasticity and facilitating uniform deformation of the α-Al matrix. And the destruction of this microstructure is allowed to accommodate more plastic strain before failure.

1 周 晓璐, "高硅铝合金中TiP的演变行为与初晶Si复合形核研究" 山东大学 2017

2 X. Liu, "Twincontrolled growth of eutectic Si in unmodified and Sr-modified Al–12.7%Si alloys investigated by SEM/EBSD" 97 : 338-347, 2015

3 F. Lasagni, "Threedimensional characterization of ‘as-cast’ and solution-treated AlSi12(Sr) alloys by high-resolution FIB tomography" 55 (55): 3875-3882, 2007

4 M. Zamani, "The role of transition metal additions on the ambient and elevated temperature properties of Al-Si alloys" 693 : 42-50, 2017

5 Z. Asghar, "The role of Ni and Fe aluminides on the elevated temperature strength of an AlSi12 alloy" 527 (527): 5691-5698, 2010

6 W. Yu, "The influence of T6 treatment on fracture behavior of hypereutectic Al-Si HPDC casting alloy" 731 : 444-451, 2018

7 H. Yang, "The grain refinement performance of Bdoped TiC on Zr-containing Al alloys" 731 : 774-783, 2018

8 S. K. Shaha, "Tensile and compressive deformation behavior of the Al–Si–Cu–Mg cast alloy with additions of Zr, V and Ti" 59 : 352-358, 2014

9 Y. Li, "Supportive strengthening role of Cr-rich phase on Al–Si multicomponent piston alloy at elevated temperature" 528 (528): 4427-4430, 2011

10 A. Tireira, "Rupture of intermetallic networks and strain localization in cast AlSi12Ni alloy: 2D and 3D characterization" 112 : 162-170, 2016

11 Y. Li, "Quantitative comparison of three Nicontaining phases to the elevated-temperature properties of Al–Si piston alloys" 527 (527): 7132-7137, 2010

12 A. R. Farkoosh, "Phase formation in as-solidified and heat-treated Al–Si–Cu–Mg–Ni alloys: thermodynamic assessment and experimental investigation for alloy design" 551 : 596-606, 2013

13 F. Nový, "Microstructure changes in a 2618 aluminium alloy during ageing and creep" 487 (487): 146-151, 2009

14 H. Yang, "Microstructure and mechanical properties at both room and high temperature of in-situ TiC reinforced Al–4.5Cu matrix nanocomposite" 767 : 606-616, 2018

15 C. L. Chen, "Investigation of mechanical properties of intermetallic phases in multi-component Al–Si alloys using hot-stage nanoindentation" 18 (18): 499-508, 2010

16 K. Bugelnig, "Influence of 3D connectivity of rigid phases on damage evolution during tensile deformation of an AlSi12Cu4Ni2 piston alloy" 709 : 193-202, 2018

17 J. -G. Jung, "Improved mechanical properties of near-eutectic Al-Si piston alloy through ultrasonic melt treatment" 669 : 187-195, 2016

18 E. R. Wang, "Improved mechanical properties in cast Al–Si alloys by combined alloying of Fe and Cu" 527 (527): 7878-7884, 2010

19 Z. Chen, "Grain refinement of hypoeutectic Al-Si alloys with B" 120 : 168-178, 2016

20 L. Bolzoni, "Grain refinement of Al–Si alloys by Nb–B inoculation. Part II: application to commercial alloys" 66 : 376-383, 2015

21 A. D. Kotov, "Formation of micrograin structure and superplastic state in alloys of the Al–Cu–Mg–Fe–Ni system" 54 (54): 340-344, 2012

22 Y. Yang, "Evolution of nickel-rich phases in Al–Si–Cu–Ni–Mg piston alloys with different Cu additions" 33 : 220-225, 2012

23 L. Han, "Effects of Nd on microstructure and mechanical properties of cast Al-Si-Cu-Ni-Mg piston alloys" 695 : 1566-1572, 2017

24 V. Abouei, "Effect of Fe-rich intermetallics on the wear behavior of eutectic Al–Si piston alloy (LM13)" 31 (31): 3518-3524, 2010

25 Y. Yang, "Effect of Cr content and heat-treatment on the high temperature strength of eutectic Al–Si alloys" 647 : 63-69, 2015

26 A. R. Farkoosh, "Dispersoid strengthening of a high temperature Al–Si–Cu–Mg alloy via Mo addition" 620 : 181-189, 2015

27 N. A. Belov, "Constituent phase diagrams of the Al–Cu–Fe–Mg–Ni–Si system and their application to the analysis of aluminium piston alloys" 53 (53): 4709-4722, 2005

28 S. K. Shaha, "Ageing characteristics and high-temperature tensile properties of Al–Si–Cu–Mg alloys with micro-additions of Mo and Mn" 684 : 726-736, 2017

29 S.K. Shaha, "Ageing characteristics and high-temperature tensile properties of Al–Si–Cu–Mg alloys with micro-additions of Cr, Ti, V and Zr" 652 : 353-364, 2016

30 X. -L. Zhou, "Absorbing formation mechanism of AlP on TiB2 substrate and their application as high-efficiency nucleating agent in Al-45Si alloy" 693 : 853-858, 2017