In situ (Mg2Si+MgO)/Mg composites fabricated from AZ91-Al2(SiO3)3 with assistance of high-energy ultrasonic field
ZHANG Song-li(张松利), ZHAO Yu-tao(赵玉涛), CHEN Gang(陈 刚)
School of Materials Science and Engineering, Jiangsu University, Zhenjiang 212013, China
Received 23 October 2009; accepted 6 September 2010
Abstract: In situ (Mg2Si+MgO)/Mg composites fabricated from AZ91-Al2(SiO3)3 under high-energy ultrasonic field were investigated by XRD, DSC and SEM. The results indicate that the size, morphology and distribution of the in situ Mg2Si particles are greatly optimized with the assistance of the high-energy ultrasonic field. The amounts of the in situ Mg2Si particles are increased, the sizes are refined, the distributions become uniform, and the morphologies are changed to smooth olive-shape or spherical shape. The amounts of brittle β-Mg17Al12 phases are decreased and the morphologies are granulated. The values of the tensile strength σb and HB hardness are increased. These are due to the cavitation effects and acoustic streaming effects induced by the high-energy ultrasonic field.
Key words: in situ composites; high-energy ultrasonic field; morphology; microstructure; mechanical property
1 Introduction
Magnesium matrix composites reinforced by particles are attractive to meet the increasing demands of advanced structural applications, e.g. automotive and aerospace systems, due to their low density, high specific stiffness, high specific strength and good thermal stability compared with pure magnesium and their alloys[1-3]. The reinforcements can be classified as ex-situ and in-situ particles according to their source in the matrix[4]. In ex-situ particles reinforced magnesium matrix composites, the particles are added into the melt from the outside, such as liquid ingot casting and powder metallurgy; in in-situ particles reinforced magnesium matrix composites, the particles are formed within the melt, such as exothermic dispersion, reactive hot pressing, self-propagating high temperature synthesis, reactive infiltration and direct melt reactions[5-8]. As for the in-situ synthesis technology, the reinforcement particles are fabricated by chemical reactions and grow up in magnesium melt. These lead to neat particle/matrix interface, good wetting ability and high interface bonding strength. Especially, the direct melt reaction is considered one of the most potential and promising techniques for commercial applications due to its simplicity, low cost and near net-shape forming capability[9].
In the present work, the mechanical effects, cavitation effects and acoustic streaming effects induced by the high-energy ultrasonic field on the microstructures and mechanical properties of the in situ Mg2Si/Mg composites fabricated from AZ91-Al2(SiO3)3 are focused on. And the effects of the high-energy ultrasonic field on the in situ Mg2Si particles and microstructures of the magnesium alloy matrix are discussed in detail.
2 Experimental
The starting materials are commercial AZ91 ingots (Al 8.78, Zn 0.65, Mn 0.19, Fe 0.001 1, Cu 0.007 9, Si 0.045 5, Ni 0.000 8, Be 0.000 9, Cl 0.001 and Mg balance, mass fraction, %) and Al2(SiO3)3 salt (AS881). Firstly, the Al2(SiO3)3 salts were dehydrated at 250 °C for 3 h in an electric furnace. The AZ91 alloy ingots were heated at 5 °C/min in graphite crucible (d100 mm×240 mm) in an electric furnace under CO2 and SF6 gaseous mixture protection. When the temperature of the melt reached 720 °C, the dehydrated Al2(SiO3)3 powder were added and pressed into the magnesium melt with a campanulate graphite mantle. After 10 min, a cylindrical amplitude lever was immersed into the magnesium about 5 mm in depth. The ultrasonic generation system was turned on. After 10 min high-energy ultrasonic operation, the magnesium melt was degassed, slag removed and refined. The magnesium melt was rested for 3 min and then was poured into a copper mould. After being cooled to the room temperature in air, the composite ingot was processed as the testing specimens.
X-ray diffractometer (Dmax2500PC) using Cu Kα radiation was used to determine the phase component of the as-prepared specimens. Optical microscope (LAICA DM2500M) and scanning electron microscope (JEOL, JSM-7001F) were used to analyze the microstructures. Tensile properties of the specimens were tested at room temperature by a computer-controlled electronic tensile testing machine (DWD-200) at a strain rate of 1.67×10-4 s-1. The tensile properties are the average values of three tests under each condition.
3 Results and discussion
3.1 Phase components
Fig.1 shows XRD pattern of the as-prepared composites fabricated with assistance of high-energy ultrasonic. As shown in Fig.1, Mg, Mg2Si, Mg17Al12 and MgO phases are observed according to Ref.[10-13]. In Mg-Al2(SiO3)3 system, some chemical reactions take place in the molten magnesium liquid according to the XRD and thermodynamics calculations results. The formations of the in-situ reinforcement phases in experiments are described as follows. In magnesium melt, the Al2(SiO3)3 salt are decomposed to SiO2 and Al2O3 according to the following reaction:
Al2(SiO3)3→3SiO2+Al2O3 (1)
Then, SiO2 and Al2O3 can react with magnesium according to the following two reactions:
4Mg+SiO2→2MgO+Mg2Si (2)
3Mg+Al2O3→3MgO+2Al (3)
Fig.1 XRD patterns of as-prepared composites fabricated with assistance of high-energy ultrasonic field
The possibility of Eqs.(2) and (3) was determined by the Gibbs free energy values calculated from thermodynamics.
As for n1A1+n2A2=n3A3+n4A4 type chemical reaction system, the reaction free energy can be calculated as
(4)
(5)
(6)
where ?cp=n3?cp(3)+n4?cp(4)+n1?cp(1)+n2?cp(2).
For simplifying the calculations, Eqs.(4)-(6) can be written as the following linear equation:
?GT=a+bT (7)
The thermodynamic parameters of the elements and compounds are listed in Table 1.
According to Ref.[14], the free energy parameters of the reactions (2) and (3) are as follows, respectively:
(8)
(9)
When the melt temperature is 993 K, =-83 420 kJ/mol, and ?GT(2)=-28 565.1 kJ/mol. This means that the reactions (2) and (3) can take place spontaneously in the above conditions. The results of the thermodynamic calculations are in concordance with the XRD results.
Table 1 Thermodynamics parameters of elements and compounds[14]
3.2 Microstructures
Fig.2 shows the SEM images of the as-prepared composites synthesized from AZ91-Al2(SiO3)3 system without and with the assistance of the ultrasonic field. It can be clearly seen that, with ultrasonic field, the in situ Mg2Si and MgO particles are distributed and dispersed uniformly in the magnesium matrix, and Mg17Al12 are dispersed in macro-scale. The morphologies of the in situ Mg2Si particles are presented in near spherical shape or smooth quadrangle-shape with size of about 2-3 μm, MgO particles in spherical shape with size of about 0.1-0.5 μm, and the Mg17Al12 intermetallic compound in massive shape, bone-shape, or long strip-shape, due to the effects of the high-energy ultrasonic field.
The cavitation effect of the high-power ultrasonic field is due to the expanding-clogging-bursting dynamical processing for the ultrasonic bubbles. When the high-power ultrasonic field is transmitted to the magnesium melt, the melt bears the tensile stress and the cavitations are born. Then, the cavitations are rapidly expanded, clogged and burst in the magnesium melt. The instantaneous local high-temperature, high press and intensive blast wave are thus created[15] and greatly contributed to the crack and peripheral-smooth for the bonding net-shape Mg2Si phases and brittle Mg17Al12 phases.
Fig.2 SEM images of composites synthesized from AZ91-Al2(SiO3)3 system without (a) and with ultrasonic field assistance (b)
When the high-power ultrasonic field is transmitted to the aluminum melt, the sonic press gradients are built from the sonic source due to the finite amplitude attenuation of the interaction of the sound wave and the viscous force of the magnesium melt. These sonic press gradients are contributed to the flowing of the melt and the circulation flow in the magnesium melt. The flowing direction of the melt under the amplitude lever is vertical-downward, and the flowing speed is fast. After reaching the bottom of the crucible and reversely moving upward, the flowing speed is reduced. The spiral vortex is formed near the end face of the amplitude lever. These induce the acoustic streaming effects: vibration and stirring.
The above effects of the high-energy ultrasonic field contribute to the diffusion of the reactants and the products. Thus, the in situ chemical reactions are speeded and the broken Mg2Si and Mg17Al12 phases distribute uniformly in the magnesium melt.
3.3 Mechanical properties
The mechanical properties of the composites fabricated without and with the assistance of ultrasonic field are listed in Table 2. It is indicated that with the assistance of the high-energy ultrasonic field, the values of the tensile strength and HB hardness are increased. The tensile strength σb, HB hardness and elongation δ are 276.24 MPa, 83.49 MPa and 3.97%, which are 1.42, 1.35 and 1.13 times those of without the assistance of the high- energy ultrasonic field, respectively.
Table 2 Mechanical properties of composites fabricated with and without assistance of ultrasonic field
Fig.3 gives the SEM images of the tensile fracture surface of the tested specimens. It can be clearly seen that the appearances of the fracture surfaces are different in size and depth with and without ultrasonic field. As shown in Fig.3(a), the tensile fracture surface shows the obvious cleavage fracture characteristics, the brittle β-Mg17Al12 phases are clearly seen on the fracture surface and become the main crack nucleating site, and the observed dimples are shallower in depth and larger in size and parts are linked along the boundaries. With ultrasonic field, the brittle β-Mg17Al12 and Mg2Si phases are refined, the ratio of the surface area to volume is increased, and the surface tension is increased. These hinder the expansion of the deformed area along the boundary of the crystal grain. As shown in Fig.3(b), the observed dimples are deeper in depth and smaller in size. The appearances of the tearing deformation inside the crystal are clearly observed, and the cleavage fracture characteristics are weakened. The fracture mechanisms are the plastic fracture and cleavage fracture.
Fig.3 SEM images of tensile fracture surface of composites synthesized from AZ91-Al2(SiO3)3 system without (a) and with (b) ultrasonic field assistance
4 Conclusions
1) In situ (Mg2Si+MgO)/Mg composites are fabricated from AZ91-Al2(SiO3)3 with the assistance of the high-energy ultrasonic field.
2) The sizes, morphologies and distributions of the in situ Mg2Si particles are more greatly optimized with high-energy ultrasonic field than those without high-energy ultrasonic field. Under the ultrasonic field, the amounts of the in situ Mg2Si particles are increased, the sizes are refined, the distribution becomes uniform, and the morphologies are changed to smooth olive-shape or spherical shape. The amounts of brittle β-Mg17Al12 phases are decreased and the morphologies are granulated.
3) The values of the tensile strength σb and HB hardness are increased, reaching 276.24 MPa and 83.49 MPa, respectively.
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(Edited by YANG Bing)
Foundation item: Project(20070299004) supported by the Specialized Research Fund for the Doctoral Program of Higher Education of China; Project(BG2007030) supported by High-tech Research Program of Jiangsu Province, China; Projects(07KJA43008, 10KJD430003) supported by Natural Science Foundation of Jiangsu Province, China
Corresponding author: ZHAO Yu-tao; Tel: +86-511-88797658; E-mail: zsl@ujs.edu.cn, zhaoyt@ujs.edu.cn
DOI: 10.1016/S1003-6326(09)60424-6