Al matrix composites reinforced with homogeneous distributed particles have been widely investigated due to their high specific stiffness , strength  and tailorable thermal-physical properties . However, the strength enhancement in homogeneous composites is usually achieved at the expense of plasticity . Recently, it has been found that inhomogeneous composites demonstrate good compatibility in strength and plasticity compared with the homogeneous distributed reinforcements . Therefore, more attention in the past decades has been paid on the design, preparation and characterization of the inhomogeneous distributed microstructure in the composites.
Lamellar Al matrix composites, whose microstructure is bio-inspired by the nacre, have been considered as candidates for light-weight armor protection materials due to their high strength and toughness. Therefore, recently, the lamellar Al matrix composites have been extensively investigated . Several advanced methods, such as mechanical rolling , slip casting , centrifugal casting  and flake powder metallurgy , have been adopted to prepare the composites with layered microstructure. Li et al. [11, 12] found that the Al matrix nanolaminated composites reinforced with carbon nanotubes or graphene demonstrated improved strength and plasticity than that of the uniform distributed composites.
Freezing-dry method has been developed recently to prepare the ceramic-based bio-inspired layered structure, which could be further infiltrated with liquid matrix to obtain the composites with pearl-like layer structure. During the freezing-dry process, the ceramic particles could be dispersed in water to build sophisticated, nacre-like architectures with the layer thickness varying from 10 to 200 μm. The microstructure of the scaffold in micron-scale could be easily modified by controlling the freezing kinetics precisely. After infiltrated with selected second phase (organic or inorganic), the biomimetic microstructure of the scaffold could also be preserved, the hard and ductile phases could be alternately arranged and both strength and toughness of the composites could be enhanced. The Deville et al.  firstly reported the preparation of the biomimetic composites based on freezing-dry method including artificial bone, ceramic-metal composites, and porous scaffolds for osseous tissue regeneration with strengths up to four times higher than those of materials currently used for implantation. Currently, most of the lamellar Al matrix composites have been prepared by the pressure-less infiltration method to avoid the breakdown of the ceramic lamellae in the scaffolds with relative low strength. The Deville et al.  firstly reported the preparation of the lamellar Al2O3p/Al-12Si composites as well by freeze-casting and vacuum infiltration method, and found that the lamellar Al2O3p/Al-12Si composites demonstrated good strength-toughness properties. Shen et al.  deeply investigated the microstructure and mechanical properties of the lamellar SiC/Al-Si-Mg composites prepared by freeze-casting and pressure-less infiltration method and found that the composites demonstrated weak orthotropic properties with maximum 722 MPa compressive strength in longitudinal direction. Shen et al.  further investigated the microstructure evolution and mechanical properties of the lamellar Al2O3-ZrO2/Al-Si-Mg composites prepared by freeze-casting and pressure-less infiltration method, and revealed the reaction between Al-12Si-10Mg matrix and ZrO2 to form (Al1−m, Sim)3Zr, Al2O3 and ZrSi2 phases. Hautcoeur et al.  fabricated the lamellar ZrO2/Al composites by freeze-casting and pressure-less infiltration method, and reported that the thermal conductivities of the composites were significantly anisotropic, which were 80 and 13W/(m·K) parallel and perpendicular to the freezing direction, respectively.
Generally, utilization of pressure during infiltration and solidification of liquid metals is beneficial for the densification of the composites . Shen et al.  utilized 2 MPa gas-pressure in vacuum atmosphere to infiltrate liquid pure Al into porous Al2O3–ZrO2 scaffolds. The few pores and breakage of the Al2O3–ZrO2 scaffolds were also found , and revealed that the Al penetration and subsequent interfacial reaction with ZrO2 would be affected significantly by the porous structure of the ceramic lamellae. However, due to the low heating and cooling rate caused by the vacuum atmosphere, the preparation process of the gas-pressure infiltration was rather time and energy consuming. Moreover, it is difficult to control the reaction between the scaffolds and Al matrix due to the long contact time . Furthermore, due to the technique restriction, it is very difficult to apply higher gas-pressure (more than 5 MPa), which is unfavorable for the infiltration and densification process. Liu et al.  explored the preparation of the lamellar SiCp/2024Al composites by freeze-casting and pressure infiltration method with infiltration pressure of 80 MPa by mechanical method. The composites demonstrated lamellar microstructure composed of alternating ceramic and metallic lamellar and high bending strength (931 MPa) and roughness (18.8 MPa·m1/2). However, the breakdown of the bridges between ceramic lamellae in the scaffolds was also found in the produced composites.
Therefore, compared with other methods, the mechanical-pressure infiltration method has the advantages in flexibility of the Al matrix, low requirement for equipment and good preservation in lamellar microstructure of the scaffold. However, the investigation of lamellar Al matrix composites prepared by freeze-drying and mechanical-pressure infiltration method has not been fully understood yet. In the present work, the Al2O3 scaffold with pearl layer structure was prepared by freezing-dry method, and eventually the lamellar Al2O3p/Al composite was fabricated by mechanical-pressure infiltration method. The microstructure and the compressive behavior of the lamellar Al2O3p/Al composite have also been investigated.
2 Materials and methods
Al2O3 particles with average size of 400 nm were provided by Dalian Luming nano-materials Co., Ltd. China. Al alloy was used as matrix alloy in the present work. The chemical composition of the Al alloy was 2.6wt.% Mg, 1.25wt.% Si, 1.1 wt.% Fe and Al balance. C. Garcia-Cordovilla et al.  and Yoshida et al.  reported that a small amount of Mg in Al alloy could decrease the surface energy significantly, while the surface energy of Al-Mg alloys was decreased from 0.99 N/m in pure Al to 0.73 N/m in Al-9.1Mg. Therefore, the Al alloy with high Mg content was chosen as the matrix to promote the infiltration of the Al matrix [22, 23]. Based on our previous work , the porous Al2O3 scaffold was initially prepared by the freezing-dry method (Figure 1a). An aqueous suspension at a solids loading of 20 vol% was prepared by mixing Al2O3 powder, Darvan 7-N (dispersant, 1.2 wt% of the Al2O3 powder, R.T. Vanderbilt Co., Connecticut, US), and glycerol (10 wt% of the solvent) into distilled water. The mixture was then milled for 24 h with zirconia balls (6 mm, the mass ratio of balls and powder is 3:1) as the ball-milled media at a rotation speed of 120 rpm. The resulting suspension was poured into a polyethylene mold (40 mm diameter, 15mm long) and placed on refrigerated equipment (−20∘C) to induce the unidirectional solidification of the slurry from the bottom to the top. As the freezing process was completed (~12 min), the frozen sample was freeze-dried at −40∘C and <10 Pa (Freeze Dryer, Beijing SongYuan Huaxing Technology Development Co. Ltd., China), for 48 h to remove the solvent. The green part was sintered in air for 4 h at 1500∘C at a constant rate of 5∘C/min, followed by naturally cooling in furnace to room temperature to prepare the Al2O3 scaffold. The porosity of the prepared Al2O3 scaffold was about 64.3%.
Later on, the lamellar Al2O3p/Al composite was prepared by mechanical-pressure infiltration method. The porous Al2O3 scaffold was put into a steel mold and then preheated at 500∘C for 2 h, while the Al matrix alloy was molted at 900∘C. Considering the densification effect and preservation of the integrality of the lamellae microstructure of the scaffolds, a pressure of 5 MPa was applied and maintained for 10 min during the infiltration process, followed by the solidification of the composites in air within 10 min (Figure 1b). Before microstructure observation and compressive tests, annealing treatment of all the samples were performed at 415∘C for 1 h and eventually cooled in air.
The morphologies of the porous Al2O3 scaffold and the lamellar Al2O3p/Al composite were observed by the Axiovert 40 MAT optical microscope (Carl Zeiss, Germany) and FEI Sirion Quanta 200 (FEI. Co. Ltd., Philips, Netherlands) scanning electron microscope (SEM). X-ray computed tomography (CT) was performed on the nanotom® (Phoenix|x-ray, Wunstorf, Germany) to reveal the 3D-distribution of the Al2O3 phase. The phase composition of the lamellar Al2O3p/Al composite were analyzed by the X-ray diffraction (XRD),whichwere performed on the Rigaku D/max-rB diffractometer with Cu-Kα radiation (0.15418 nm) and the scanning speed was set at 2∘/min.
The density of the lamellar Al2O3p/Al composite samples (10×10×2 mm) was measured using Archimedes principle according to ASTM B311-17, and four samples have been tested to improve the statistical significance of the results. The hardness tests were carried out on HBS210-3000 Brinell hardness tester according to ASTM E10-07a. The dimensions of hardness test samples were 15×15×4 mm. During the hardness test, 187.5 kgf load was applied for 30 s, and five samples have been tested to improve the statistical significance of the results. Compressive tests were performed on Instron 5569 universal electrical testing machine (Instron Co., USA) with a speed of 0.1 mm/min according to ASTM E9-89a. The dimensions of the compressive test samples were 4×4×5 mm. The compressive tests were performed on the transverse direction (parallel to the Al2O3 layers) and perpendicular direction (vertical to the Al2O3 layers) to reveal the effect of the distribution of the Al2O3 phase. In order to observe the fracture behavior of the Al layers and the Al2O3p/Al layers, the bending fracture surface of the lamellar Al2O3p/Al composite were analyzed by FEI Sirion Quanta 200 SEM.
3 Results and discussion
Representative microstructure of the porous Al2O3 scaffold prepared by the freezing-dry method is shown in Figure 2. The Al2O3 scaffold demonstrated aligned lamellar porous structure, which was parallel to the growth direction of the ice (Figure 2a). Moreover, the scaffold was constituted by the Al2O3 layer and interlayer (Figure 2b), whose thickness was about 20 and 8 μm, respectively. The paralleled Al2O3 layer-interlayer and interlayer-interlayer were connected by the thin Al2O3 bridges (Figure 2c).Moreover, the Al2O3 layer and interlayer were also porous, which were formed by the individual Al2O3 particles (Figure 2d).
X-ray CT characterization of the lamellar Al2O3p/Al composite is shown in Figure 3. The degree of X-ray attenuation depends on both the density and the atomic number of the material composing the samples, and higher density and higher atomic numbers result in higher attenuation of X-rays, which then show brighter colors in the processed image . The samples were composed by the lamellar Al2O3p/Al composite (marked by green braces) and the Al matrix (marked by yellow braces), as shown in Figure 3b and 3c.Moreover, the samples were composed of four components, which could be distinguished by four colors. The lamellar Al2O3p/Al composite was mainly composed of dark gray, light grey and bright regions, while the Al matrix was mainly composed of light grey and black regions. The light grey phase was Al matrix, while the dark gray region was assigned to the Al2O3 layers infiltrated with Al matrix. The black regions, which were further confirmed to be graphite impurities, were mainly found in Al matrix, and were not observed in the composites. The bright phase was confirmed by EDS analysis to be the Fe-rich phase. It is clear that the lamellar Al2O3p/Al composite demonstrated well lamellar structure of the Al2O3.
The representative microstructure of the lamellar Al2O3p/Al composite has been shown in Figure 4. The bright grey and dark grey areas in Figure 3 were Al and Al2O3/Al, respectively, which revealed the layered structure of the composites. Meanwhile, several individual bright phases with irregular sharp were also found in the composite (Figure 4a). Further EDS analysis indicated that the bright phases were rich with Fe elements, which might be introduced into the composites during infiltration process as impurities. Higher magnification observation indicated that the Al matrix has been infiltrated well into the large pores of the Al2O3 scaffold (Figure 4b). However, the Al2O3 layers, interlayers and bridges have not been fully infiltrated, which has been marked out by the red circles in Figure 4b. Correspondingly, the measured relative density of the prepared lamellar Al2O3p/Al composite was about 92.3%. Since the porosity of the prepared Al2O3 scaffold was about 64.3%, the real weight percentage of the Al2O3 was about 48.2%. Pressure infiltration method has been widely used to infiltrate the Al matrix into the ceramic scaffolds with uniform pore structure . However, high infiltration temperature and pressure, which could overcome the poor wettability and high infiltration resistance, is usually used to achieve full densification . In the present work, in order to avoid the destruction of the lamellar porous structure in Al2O3 scaffold, relative low infiltration pressure (5 MPa), which was lower than in other system (usually higher than 10 MPa) [28, 29], was applied. It was mainly due to the relative low compressive strength of the Al2O3 scaffold (measured to be about 15 MPa at 500∘C). However, the micro-scale pores between Al2O3 interlayer were fully filled with the Al while the submicron-scale pores within the Al2O3 interlayer were rarely infiltrated. Therefore, the infiltration parameters (such as temperature and pressure) should be further optimized for the fully densification of the composites.
XRD analysis of the lamellar Al2O3p/Al composite has been shown in Figure 5. Only the diffraction peaks of the Al, Al2O3 and very small content Mg2Si phases were found, while the Mg2Si phase is the common strengthening precipitates in Al-Mg-Si matrix composites [30, 31]. However, no significant diffraction peaks of the Fe-rich phases were detected, indicating the content of the Fe-rich phases was rather low. It should be noted that the Al2O3 could react with Mg element to form MgAl2O4, which has been widely reported in Al2O3/Al composites prepared by pressure-less infiltration method [32, 33]. However, no significant presence of the MgAl2O4 phase has been found in the present work. It might be due to the short preparation time (about 10 min) used in the present work.Usually, the chemical reaction is strongly related to the atmosphere temperature and contact time. Since the diffusion rate of Mg element in solid Al is much lower than that in molten Al , the reaction to form MgAl2O4 phase is mainly occurred at the interface between Al2O3 and molten Al-Mg matrix. However, due to the short contact time in the present work, the reaction should be very weak and lower than the XRD detection accuracy, which agrees well with the interfacial microstructure observation results in Al2O3 particles reinforced 6061Al and 2024Al composites prepared under similar parameters [35, 36].
The hardness of the lamellar Al2O3p/Al composite in the transvers (parallel to the growth direction of the ice) and perpendicular (vertical to the growth direction of the ice) directions were 212.1±5.5 and 209.7±7.2 HB, while the hardness of the Al matrix was 84.4±4.7HB, respectively. The hardness of the lamellar Al2O3p/Al composite increased about 150% than that of the Al matrix. However, it is difficult to reveal the anisotropy characters of the lamellar Al2O3p/Al composite since the hardness values in different directions were very close. The representative compressive curves of the lamellar Al2O3p/Al composite in transvers and perpendicular directions have been shown in Figure 6. For comparison, the compressive curve of the Al matrix was also shown in Figure 6. Regardless of the test direction, it is clear that the compressive strengths of the lamellar Al2O3p/Al composite were higher than that of the Al matrix alloy. The compressive strengths of the lamellar Al2O3p/Al composite in transvers and perpendicular directions were 748.2±17.3 and 328.6±11.7 MPa, which increased 234.5% and 46.9% than that of the Al matrix alloy (223.7±5.8 MPa), respectively. Meanwhile, the fracture behavior was also changed from plastic to brittle fracture character after the introduction of the Al2O3 scaffold since the compressive stress increased linearly to maximum before failure. Moreover, the compressive curve of the lamellar Al2O3p/Al composite in perpendicular direction demonstrated ladder-like character, which is an important characteristic in lamellar composites and corresponds to the crack deflection along the Al2O3 layer or interlayer . However, the compressive curve of the lamellar Al2O3p/Al composite in transvers direction demonstrated linear character without ladder-like deflection or deformation. It was mainly due to the holistic strengthening effect of the Al2O3 scaffold attributed to the connection and bridging of the Al2O3 layer or interlayer.
Moreover, the compressive strength of the lamellar Al2O3p/Al composite in transvers direction (748.2 MPa) was 127.7% higher than that in the perpendicular direction (328.6 MPa). Therefore, the lamellar Al2O3p/Al composite demonstrated significant compressive anisotropic behavior. Shen et al.  reported that the anisotropic compressive behavior of the lamellar SiCp/Al composites prepared by freeze casting and pressure-less infiltration. The compressive strength of the composites loaded along the longitudinal direction was about 100–200MPa higher than the perpendicular direction . However, Liu et al.  reported that the mechanical properties of the lamellar SiC/2024Al composites prepared by freeze casting and pressure infiltration method (infiltrated at 80 MPa) were quasi-isotropy. The values of the flexural strength, fracture toughness and the hardness of the composites were very close in the longitudinal and perpendicular directions, which were mainly related to the breakdown of the bridges between ceramic lamellae in the scaffolds . Attributed to the bridging effect of the porous scaffold, the stress could be distributed equally on composite layers when the compressive load was paralleled to the freezing direction . Therefore, the anisotropic characters in the mechanical properties represent the integrality of the lamellae microstructure (especially the bridging layers), which implies that the anisotropic microstructure of the scaffold has been well preserved in the present work.
Currently, several methods, such as pressure-less infiltration [13, 14, 15], gas-pressure infiltration  and high mechanical-pressure infiltration methods , have been reported to prepare lamellar Al matrix composites. Pressure-less infiltration method is suitable for large-scale composites preparation since no pressure device is needed . However, due to the poor wettability between the ceramic particles and Al matrix, the option for the Al matrix is usually Al-Mg-Si alloy since the Mg and Si element could improve the wettability. Therefore, several high strength Al alloy, such as 7XXX alloy, could not be used, and the design flexibility of the Al matrix and the corresponding strength of the composites are limited. Gas-pressure infiltration expands the option list of the Al matrix. However, the gas-pressure infiltration is usually preformed in high temperature vacuum furnace, which is usually very expensive. Moreover, due to the low heating and cooling rate caused by the vacuum atmosphere, the preparation process of the gas-pressure infiltration was rather time and energy consuming, and it is difficult to control the reaction between the scaffolds and Al matrix due to the long contact time . Furthermore, due to the technique restriction, it is very difficult to apply higher gas-pressure (more than 5 MPa), which is unfavorable for the infiltration and densification process. The high mechanical-pressure infiltration method (more than 80 MPa) has the advantages in densification effect . However, the breakdown of the bridges between ceramic lamellae in the scaffolds was also found in the produced composites due to low strength of the scaffolds. Compared with other methods, the mechanical-pressure infiltration method has the advantages in flexibility of the Al matrix, low requirement for equipment and good preservation in lamellar microstructure of the scaffold. However, the infiltration parameters should be controlled carefully.
The fracture surface of the lamellar Al2O3p/Al composite has been shown in Figure 7. The lamellar Al2O3p/Al composite demonstrated significant layered-like fracture behavior. The fracture of the Al area was mainly characterized by the larger tearing edges (as pointed out by blue circle in Figure 7b). Moreover, small tearing edges of Al around Al2O3 particles (as pointed out by yellow circle in Figure 7b), which were the representative phenomena in particles reinforced Al matrix composites , were found in the fracture of the Al2O3p/Al area. Furthermore, due to the mismatched deformability, weak debonding was observed between Al and Al2O3p/Al layers. During the loading process, both the Al and Al2O3p/Al layers participated the strengthening effect. The weak debonding behavior implied that the interfacial bonding between Al and Al2O3p/Al layers was rather strong, which is beneficial for the strengthening effect of Al2O3p/Al composite scaffold and leads to the high compressive strength in transvers direction (about 748.2 MPa). However, the strong interfacial bonding between Al and Al2O3p/Al layers is unfavorable for the crack deflection,which is a main strengthening and toughening mechanism in lamellar composites. The compressive strengths of the lamellar Al2O3p/Al composite in perpendicular direction were rather low (about 328.6MPa). Therefore, the interfacial bonding properties should be further optimized to improve the mechanical properties in different directions.
In the present work, lamellar Al2O3p/Al composite has been prepared by freezing-dry and mechanical-pressure infiltration method. After the infiltration of Al matrix, the lamellar Al2O3p/Al composite also demonstrated well lamellar structure of the Al2O3. The Al matrix has been infiltrated well into the large pores of the Al2O3 scaffold, while the Al2O3 layers, interlayers and bridges have not been fully infiltrated. The hardness of the lamellar Al2O3p/Al composite was isotropic in transvers and perpendicular directions. However, the compressive strength of the lamellar Al2O3p/Al composite in transvers direction was 748.2±17.3 MPa. It should be noted that the lamellar Al2O3p/Al composite demonstrated significant compressive anisotropic behavior, while the compressive strength in transvers direction was 127.7% higher than that in the perpendicular direction. The anisotropic characters in the compressive properties represent the integrality of the lamellae microstructure (especially the bridging layers), which also implies that the anisotropic microstructure of the scaffold has been well preserved in the present work. The fracture surface of the lamellar Al2O3p/Al composite demonstrated significant layered-like fracture behavior. It indicates that the interfacial bonding between Al and Al2O3p/Al layers is rather strong, which is beneficial for higher strength in transvers direction but leads to lower strength in perpendicular direction.
This work was supported by the National Natural Science Foundation of China (grant numbers 51871073, 61604086, 51501047, 51571069, 51771063 and U1637201), China Postdoctoral Science Foundation (grant number 2016M590280 and 2017T100240), Heilongjiang Postdoctoral Foundation (grant number LBH-Z16075) and the Fundamental Research Funds for the Central Universities (grant numbers HIT.NSRIF.20161 and HIT. MKSTISP. 201615).
Alanka S, Ratnam C, Prasad BS. An effective approach to synthesize carbon nanotube-reinforced Al matrix composite precursor. Sci Eng Compos Mater. 2018;25(5):983–91.
Wang P, Chen G, Jiang L, Li D, Wu G. Effect of thermal exposure on the microstructure of the interface in a Grf/Al composite. Sci Eng Compos Mater. 2016;23(6):751–7.
Daneshmand S, Behnam Masoudi B. Investigation and optimization of the electro-discharge machining parameters of 2024 aluminum alloy and Al/7.5% Al2O3 particulate-reinforced metal matrix composite. Sci Eng Compos Mater. 2018;25(1):159–72.
Chao ZL, Zhang LC, Jiang LT, Qiao J, Xu ZG, Chi HT, et al. Design, microstructure and high temperature properties of in-situ Al3Ti and nano-Al2O3 reinforced 2024Al matrix composites from Al-TiO2 system. J Alloys Compd. 2019;775:90–297.
Chen S, Fu D, Luo H, Wang Y, Teng J, Zhang H. Hot workability of PM 8009Al/Al2O3 particle-reinforced composite characterized using processing maps. Vacuum. 2018;149:297–305.
Yu Z, Liu J, Zhu W, Wei X. Optimizing mechanical properties of bio-inspired composites through functionally graded matrix and microstructure design. Compos Struct. 2018;206:621–7.
Qin L, Fan M, Guo X, Tao J. Plastic deformation behaviors of Ti-Al laminated composite fabricated by vacuum hot-pressing. Vacuum. 2018;155:96–107.
Ortiz AL, Candelario VM, Moreno R, Guiberteau F. Near-net shape manufacture of B4C–Co and ZrC–Co composites by slip casting and pressure-less sintering. J Eur Ceram Soc. 2017;37(15):4577–84.
Wang K, Zhang ZM, Yu T, He NJ, Zhu ZZ. The transfer behavior in centrifugal casting of SiCp/Al composites. J Mater Process Technol. 2017;242:60–7.
Xu R., Tan Z., Fan G., Ji G., Xiong D.B., Guo Q., Su Y., Li Z., Zhang D., High-strength CNT/Al-Zn-Mg-Cu composites with improved ductility achieved by flake powder metallurgy via elemental alloying, Compos. Part. A-Appl. S., 2018, 111, 1-11.
- Export Citation
Xu R., Tan Z., Fan G., Ji G., Xiong D.B., Guo Q., Su Y., Li Z., Zhang D., High-strength CNT/Al-Zn-Mg-Cu composites with improved ductility achieved by flake powder metallurgy via elemental alloying, Compos. Part. A-Appl. S., 2018, 111, 1-11.)| false 10.1016/j.compositesa.2018.05.012
Chen M, Fan G, Tan Z, Xiong D, Guo Q, Su Y, et al. Design of an efficient flake powder metallurgy route to fabricate CNT/6061Al composites. Mater Des. 2018;142:288–96.
Jiang Y., Tan Z., Xu R., Fan G., Xiong D.B., Guo Q., Su Y., Li Z., Zhang D., Tailoring the structure and mechanical properties of graphene nanosheet/aluminum composites by flake powder metallurgy via shift-speed ball milling, Compos. Part. A-Appl. S., 2018, 111, 73-82.
- Export Citation
Jiang Y., Tan Z., Xu R., Fan G., Xiong D.B., Guo Q., Su Y., Li Z., Zhang D., Tailoring the structure and mechanical properties of graphene nanosheet/aluminum composites by flake powder metallurgy via shift-speed ball milling, Compos. Part. A-Appl. S., 2018, 111, 73-82.)| false 10.1016/j.compositesa.2018.05.022
Deville S, Saiz E, Nalla RK, Tomsia AP. Freezing as a path to build complex composites. Science. 2006 Jan;311(5760):515–8.
Shaga A, Shen P, Sun C, Jiang Q. Lamellar-interpenetrated Al–Si– Mg/SiC composites fabricated by freeze casting and pressure-less infiltration. Mater Sci Eng A. 2015;630:78–84.
Guo RF, Lv HC, Shen P, Hu ZJ, Jiang QC. Lamellar-interpenetrated Al-Si-Mg/Al2O3-ZrO2 composites prepared by freeze casting and pressure-less infiltration. Ceram Int. 2017;43(3):3292–7.
Hautcoeur D., Lorgouilloux Y., Leriche A., Gonon M., Nait-Ali B., Smith D.S., Lardot V., Cambier F., Thermal conductivity of ceramic/metal composites from preforms produced by freeze casting, Ceram. Int., 2016, l42, 14077–14085.
Yu Z, Yang W, Zhou C, Zhang N, Chao Z, Liu H, et al. Effect of ball milling time on graphene nanosheets reinforced Al6063 composite fabricated by pressure infiltration method. Carbon. 2019;141:25–39.
Guo RF, Guo N, Shen P, Yang LK, Jiang QC. Effects of ceramic lamellae compactness and interfacial reaction on the mechanical properties of nacre-inspired Al/Al2O3–ZrO2 composites. Mater Sci Eng A. 2018;718:326–34.
Liu Q, Ye F, Gao Y, Liu S, Yang H, Zhou Z. Fabrication of a new SiC/2024Al co-continuous composite with lamellar microstructure and high mechanical properties. J Alloys Compd. 2014;585:146–53.
Garcia-Cordovilla C, Louis E, Pamies A. Surface tension of binary and ternary aluminium alloys of the systems Al-Si-Mg and Al-Zn-Mg. J Mater Sci. 1986;21:5247–52.
Matsunaga T., Ogata K., Hatayama T., Shinozaki K., Yoshida M., Effect of acoustic cavitation on ease of infiltration of molten aluminum alloys into carbon fiber bundles using ultrasonic infiltration method, Compos. Part. A-Appl. S., 2007, 3: 771-778.
Wang X, Wang C, Chen G, Yang W, Zhang Z. Wetting behavior of Al–Mg alloys on carbon fiber fabric. Surf Rev Lett. 2013;20(03n04):1350036.
Shao P., Yang W., Zhang Q., Meng Q., Tan X., Xiu Z., Qiao J., Yu Z., Wu G., Microstructure and tensile properties of 5083 Al matrix composites reinforced with graphene oxide and graphene nanoplates prepared by pressure infiltration method, Compos. Part. A-Appl. S., 2018, 109, 151–162.
- Export Citation
Shao P., Yang W., Zhang Q., Meng Q., Tan X., Xiu Z., Qiao J., Yu Z., Wu G., Microstructure and tensile properties of 5083 Al matrix composites reinforced with graphene oxide and graphene nanoplates prepared by pressure infiltration method, Compos. Part. A-Appl. S., 2018, 109, 151–162.)| false 10.1016/j.compositesa.2018.03.009
Hu L, Zhang Y, Dong S, Zhang S, Li B. In situ growth of hydroxyapatite on lamellar alumina scaffolds with aligned pore channels. Ceram Int. 2013;39(6):6287–91.
Morankar S, Mandal M, Kourra N, Williams MA, Mitra R, Srirangam P. X-ray tomography study on porosity and particle size distribution in in situ Al-4.5Cu-5TiB2 semisolid rolled composites. JOM. 2019;71(11):1–9.
Xin L, Tian X, YangW, Chen G, Qiao J, Hu F, et al. Enhanced stability of the Diamond/Al composites by W coatings prepared by the magnetron sputtering method. J Alloys Compd. 2018;763:305–13.
Yang W, Zhao Q, Xin L, Qiao J, Zou J, Shao P, et al. Microstructure and mechanical properties of graphene nanoplates reinforced pure Al matrix composites prepared by pressure infiltration method. J Alloys Compd. 2018;732:748–58.
Yang W, Chen G, Wang P, Qiao J, Hu F, Liu S, et al. Enhanced thermal conductivity in Diamond/Aluminum composites with tungsten coatings on diamond particles prepared by magnetron sputtering method. J Alloys Compd. 2017;726:623–31.
Yang W, Chen G, Qiao J, Zhang Q, Dong R, Wu G. Effect of Mg addition on the microstructure and mechanical properties of SiC nanowires reinforced 6061Al matrix composite. Mater Sci Eng A. 2017;689:189–94.
Jiang H, Xu Z, Xi Z, Jiang L, Gou H, Zhou C, et al. Effects of pulse conditions on microstructure and mechanical properties of Si3N4/6061Al composites prepared by spark plasma sintering (SPS). J Alloys Compd. 2018;763:822–34.
Yang WS, Fuso L, Biamino S, Vasquez D, Vega Bolivar C, Fino P, et al. Fabrication of short carbon fibre reinforced SiC multilayer composites by tape casting. Ceram Int. 2012;38(2):1011–8.
Lee D, Park W, Lee DB. Effects of the injection temperature of N2 gas on pressure-less infiltration for fabricating Al-Mg/Al2O3 composites. Met Mater Int. 2008;14(4):419–23.
Chang H, Higginson RL, Binner JG. Interface study by dual-beam FIB-TEM in a pressureless infiltrated Al(Mg)-Al2O3 interpenetrating composite. J Microsc. 2009 Jan;233(1):132–9.
Sreekumar VM, Pillai RM, Pai BC, Chakraborty M. Evolution of MgAl2O4 crystals in Al-Mg-SiO2 composites. Appl. Phys. Adv Mater. 2008;90:745–52.
Xu Z, Yan J, Wu G, Kong X, Yang S. Interface structure and strength of ultrasonic vibration liquid phase bonded joints of Al2O3p/6061Al composites. Scr Mater. 2005;53(7):835–9.
Luan BF, Wu GH, Liu W, Hansen N, Lei TQ. High strength Al2O3p/2024Al composites – effect of particles, subgrains and precipitates, Mater. Sci. Tech-Lond. 2005;21:1440–3.
Han D, Mei H, Xiao S, Xia J, Gu J, Cheng L. Porous SiCnw/SiC ceramics with unidirectionally aligned channels produced by freeze-drying and chemical vapor infiltration. J Eur Ceram Soc. 2017;37(3):915–21.
Xu ZG, Jiang LT, Zhang Q, Qiao J, Wu GH. The microstructure and influence of hot extrusion on tensile properties of (Gd+B4C)/Al composite. J Alloys Compd. 2017;729:1234–43.