1. Introduction

With the development of the semiconductor and microelectronics industries, microelectronic devices are developing towards miniaturization, high performance and high-power consumption, meaning that the heat generated is multiplied, which puts forward new requirements for thermal management materials with enhanced and comprehensive thermal performances [1,2,3,4,5]. Electronic packaging materials play an important role in heat dissipation of microelectronic devices, and nearly 30% of the current microelectronic performances are limited by electronic packaging materials [6]. An ideal electronic packaging material should have a high thermal conductivity (>100 W m⁻¹ K⁻¹) to maximize heat dissipation [6,7]. Meanwhile, it should possess a lower coefficient of thermal expansion, which can be tailored in a wide range (7~16 K⁻¹) to match the substrate material, like Si or GaAs semiconductor devices, in order to reduce the thermal stress and fatigue in the working conditions [6,8]. In addition, low density is also a favorable property that should be taken into consideration for packaging materials. However, traditional packaging materials, including Al, Cu, Cu-W, C-Mo, and Kovar alloys, have difficulty satisfying the requirements of advanced electronic applications [9,10]. For instance, pure Al possesses favorable thermal conductivity as high as 217 W m⁻¹ K⁻¹, but suffers a unacceptable coefficient of thermal expansion of 23.2 K⁻¹, which limits the utilization of pure Al in advanced electronic applications [11,12,13].

Aluminum matrix composites as packaging materials have been widely investigated for their good economy and processability [14]. By adding high fractions of particle additives with low coefficients of thermal expansion, the thermal expansion behavior of the composites would be restricted significantly [4,7,9,15,16,17,18]. Meanwhile, the thermal conductivity of the composites can also be improved, or at least remain within acceptable values. The influences of adding diamond [19,20,21,22,23,24], TiC [17], Si₃N₄ [25], cBN [16], or SiC [10,18,26,27,28] via different techniques on the thermal behaviors of aluminum matrix composites were deeply studied. Recently, Si particles were suggested to be a potential additive for aluminum matrix composites due to their low coefficients of thermal expansion, high thermal conductivity and low density [7,8,9,15,29,30,31]. Moreover, superior to other ceramic additives like SiC, diamond and Si₃N₄, Al/Si composites demonstrate a much lower cost and good recyclability, since Al/Si composites can be recycled and processed into Al-Si alloys, which are a series of cast Al alloys widely used in the structural parts of machines. A variety of methods are adopted to prepare Al/Si composites, including squeeze casting [32,33], gas-pressured infiltration [34], vacuum pressure infiltration [35,36,37], spray atomization and deposition [38], spark plasma sintering (SPS) [15,16,22,23,24,39], hot pressing [40,41,42], etc. These methods can be classified into two categories: powder metallurgy and liquid phase methods. Generally, liquid phase methods are cheaper, but it is difficult to prepare high-density Al/Si composites with high fractions of Si compared with powder metallurgy represented by SPS. SPS is identified as a non-conventional powder consolidation method, which employs electric current directly through the powders. By discharging between the powder particles, it can produce spark plasma and high local temperatures, making some components soften or even partially melt and then fill the spaces between other particles and integrate together. Thus, SPS is very suitable for preparing high-density composites composed of matrixes and reinforced phases with significantly different melting points, including Al/Si composite systems. However, SPS ovens usually possess complex and expensive pulse power supplies and corresponding controlling systems, which make SPS ovens huge and expensive, and not beneficial for large-scale industrial production. New powder metallurgy sintering techniques and new equipment are still strongly in demand.

In this paper, a novel powder sintering technique developed by our group, named fast hot-pressing sintering (FHP), was employed to prepare Al/Si composites with a wide Si volume ratio. FHP can also achieve an ultrahigh heating rate, similar to the SPS technique, to satisfy the special requirements of Al and Si powder sintering. In the meanwhile, compared with SPS method, no complex and expensive pulse power supply is employed in the design of FHP, which made the cost of the FHP oven less than a quarter of that of the SPS oven with the same processing capability. The optimized FHP sintering parameters to prepare Al/Si composite samples via the FHP technique were determined first, and the thermal performances of Al/Si composite samples with Si volume ratios of 12 vol.%, 27 vol.%, 40 vol.%, 50 vol.% and 70 vol.% were studied. Kinds of thermal conductivity models are employed to investigate the relationship between Si volume ratios and thermal performances. The results show that thermal performances of the Al/Si composite prepared via the FHP technique are comparable with those prepared via the SPS technique. Given its economy, FHP is believed to be a promising technique to prepare Al/Si composite packaging material for electronic devices.

2. Materials and Experiments

2.1. Materials

Pure Al powders with particle sizes of around 100 μm were purchased from SCM Metal Products, Inc (Suzhou, China), and pure Si powders with particle sizes of around 10 μm were purchased from Ruiteng Alloy Materials Co. Ltd. (Nangong, China).

2.2. Synthesis of Al/Si Composites via Fast Hot-Pressing Sintering

The Al/Si composites with different component were sintered via a fast hot-pressing sintering oven (FHP-828, Haaten Technology Co. Ltd., Suzhou, China). The FHP technique is designed by Dr. Jianping Jia and originated from Haaten Technology Co. Ltd, Suzhou, China. The scheme of the fast hot-pressing sintering oven is shown in Scheme 1. The core part of the FHP oven includes a vacuum chamber, a high voltage direct current power supply, a pair of electrode indenters, and an appropriate mold (usually made of graphite or hard alloy). In the FHP technique, the material is directly heated up by use of a direct current at an ultrahigh heating rate of up to 1000 °C min⁻¹, under the high pressure provided by the intender. In summary, the sintering time in the FHP technique is much shorter than that of the traditional vacuum hot-pressing method, and comparable with SPS. Meanwhile, the FHP oven possesses some advantages compared to the SPS equipment, such as a low economic cost, simple design, small volume, ease of maintenance, the simplicity of automatic production, etc., which make FHP a promising technique to prepare advanced materials via the powder sintering route, including advanced metals or alloys, ceramics, and complex composites.

Typically, the Al/Si composite samples are disk shaped (Φ12 × 2~3 mm) and prepared with the following procedures: (1) Al powders and Si powders with different volume ratios (the Si volume ratios are 12 vol.%, 27 vol.%, 40 vol.%, 50 vol.% and 70 vol.%, respectively, and the corresponding samples are named Al-12Si, Al-27Si, Al-40Si, Al-50Si, Al-70Si) were mixed thoroughly, and then added into the hard alloy mold lined with graphite paper, followed by sufficient shaking of the mold to make the powders mix homogeneously; (2) the mold was transferred to the press machine for pre-pressing to ensure the powders would not spill out of the mold; and (3) the mold was, at last, transferred to the FHP oven, and when the vacuum degree was lower than 10 Pa, the temperature and press program started. The program was performed as follows: (1) firstly, the press program started, and the pressure came up to the settled value within 1 min (Table 1); (2) the temperature program started successively, and the heating rate was set to 100 °C min⁻¹ until the temperature of the mold reached 100 °C below the target temperature; (3) then the heating rate was changed to 50 °C min⁻¹ until the temperature of the mold reached to the target temperature; (4) the temperature and pressure are maintained for certain time; and (5) after cooling with the FHP-828 oven, the Al/Si composite samples were finally prepared.

In order to determine the optimized FHP sintering parameters, Al-70Si was chosen as the representative sample, and 3 series of orthogonal experiments were carried out to find the optimized sintering temperature, sintering pressure and holding time. These parameters show great influence on the real density, which would surely affect the thermal properties. The details of experiments are exhibited in Table 1.

The Al/Si composite samples need some after-treatment before further characterizations. The graphite paper stuck to the surface of the samples was removed by sandblasting. Then, the samples were polished by polishing machine (YMPZ-2-300, Metallurgical Equipment Co. Ltd., Shanghai, China) with sandpapers of 400, 800 and 1200 mesh in succession. At last, the Al/Si composite samples were polished with a polishing cloth with a nano-diamond suspension, and samples with a metallic luster were finally obtained. An Al/Si composite disk sample with 70 vol.% Si is shown in Figure 1.

2.3. Characterization

The real densities of samples were measured with a densitometer (PMDT AR-150PM, Hongtuo Equipment Co. Ltd., Dongguan, China). The relative density is calculated by dividing the real density by the theoretical density based on the densities of pure Al and Si together with the volume ratio. The microscopic morphology was examined by scanning electronic microscopy (SEM, S-4800, Hitachi, Japan). The crystal structures were studied with an X-ray diffractometer (XRD, D/MAX-2500, Rigaku, Japan).

The thermal diffusivity (α, m² s⁻¹) was measured with a laser flash Analyzer (LFA 467 HyperFlash, NETZSCH Analyzing & Testing, Selb, Germany). The specific heat capacity (C_p, J kg⁻¹ K⁻¹) was measured with a differential scanning calorimeter (DSC 214, NETZSCH Analyzing & Testing, Selb, Germany). Thus, the thermal conductivity (k, W m⁻¹ K⁻¹) could be calculated with Equation (1):

k = α × C_p × ρ_r(1)

The coefficient of thermal expansion (CTE) was measured by a dilatometer (DIL 402C, NETZSCH Analyzing & Testing, Selb, Germany). The samples were cuboid shaped, with a size of 4 × 4 × 25 mm, prepared with the same procedures of Section 2.2. The testing temperature was set as room temperature, and the testing atmosphere was high pure nitrogen.

3. Results and Discussion

3.1. Optimization of FHP Sintering Process

The parameters of the sintering process, including the sintering temperature, pressure, holding time, etc., play crucial roles in the successful preparation of powder-sintered products. During the sintering of Al/Si composites with different ratios, it was observed that the size and density of the pores inside the sintered material gradually decreased with the increase in Si content. In order to minimize the influence of porosity on the sintering quality, the samples with the highest silicon content (70 vol.%, no pores observed) were selected as the representative to adjust the sintering parameters of FHP method. The orthogonal experiments were carried out to study the influences of sintering temperature, pressure and holding time on the properties of the as-prepared Al-70Si samples.

3.1.1. Sintering Temperature

The sintering temperature is one of the most important factors to control the softening and flowability of the powders (i.e., the plastic deformation ability), which would further affect the final density. As can be seen in Figure 2a, the density increases with the sintering temperature up to the temperature of 470 °C, and then decreases. The highest density reaches 2.44 g cm⁻³ at 470 °C. The softening temperature of pure Al is about 300 °C, and the plastic deformation ability of Al increases with the temperature. Meanwhile, Si has a much higher melting point of 1410 °C, resulting in Si particles not possessing plastic deformation abilities under the sintering temperature. Hence, it should be noted here that Al forms the continuous phase and Si forms the dispersed phase in the Al/Si composite prepared in this work. In the initial stage, a greater plastic deformation ability makes the Al powders more easily to bind with the Si powders and integrate together, which would increase the density of the Al/Si composite and ensure the thermal conductivity of the final product. The fluidity of Al increases gradually with the sintering temperature, allowing full contact of the Al/Si phases to reduce the sintering porosity. The decrease in porosity led to an increase in the density of the sintered bulk with a temperature increase in the range of 440–470 °C. However, the flowable Al would overflow from the gaps between molds under high pressure, due to its excessive fluidity induced by the high temperature (475 °C), which directly reduced the percentage of Al in the final sintered bulk. The loss of Al with a higher density (ρ_Al = 2.7 g cm⁻³, ρ_Si = 2.33 g cm⁻³) makes the density decrease slightly.

It is necessary to know the phase composition to calculate the theoretical density. Therefore, XRD analysis was employed (Figure 3). The XRD patterns of the Al-70Si composite samples prepared at different sintering temperatures are all composed of two groups of peaks, one for pure Al (JCPDS No. 04-0787), and the other for pure Si (JCPDS No. 27-1402), and no peaks related other phase in the phase diagram of Al-Si alloy can be observed, implying that no evidential solid solution phase was left after the FHP sintering. On the one hand, the solubilities of Al or Si in each other are both ultra-low at room temperature; on the other hand, even a temperature of 475 °C is far below the eutectic point of Al-Si system. Thus, it can be concluded that the Al-Si composites are almost composed of pure Al and Si, and the theoretical density could be directly calculated based on the volume ratio of Al and Si. Thus, the theoretical density of Al-70Si is calculated to be 2.441 g cm⁻³, and the highest relative density of the A-70Si sample prepared at 470 °C is nearly 100% (Figure 2b), implying that the densification of A-70Si can reach the limit when the sintering temperature is 470 °C.

SEM was employed to study the microscopic morphology of surfaces of the Al-70Si composite samples prepared at different sintering temperatures, in order to further evaluate the relationship between densification and sintering temperature (Figure 4). Cracks can be clearly observed in the sample prepared at 450 °C, and as the sintering temperature increases, the number of cracks reduces and the size of cracks becomes small, suggesting that the integration between Al and Si is improved with the temperature increase. As a result, the density increases up to 470 °C. Therefore, a temperature of 470 °C should be the optimal sintering temperature.

3.1.2. Sintering Pressure

The sintering pressure shows great influence on the density in the powdering technique. Typically, in the powdering sintering technique, within the pressure limit that the mold can bear, the density will increase with the pressure. The Al-70Si composite prepared via the FHP technique also agrees with this regulation. The density keeps increasing from 100 MPa to 300 MPa, and the relative density reaches nearly 100% when the pressure arrives 300 MPa (Figure 5). As the sintering pressure increases, the contact between Al and Si powders becomes closer, which would decrease the resistance of the sample, and the current grows. Additionally, the plastic deformation ability of Al powders is also enhanced with the sintering temperature and the sintering current. As a result, the cracks disappear at a high sintering pressure, and the Al matrix becomes denser, which can be observed in the SEM images (Figure 6). XRD was also employed to study the microstructures of the samples prepared at different sintering pressures, and it is not unexpected that the XRD patterns share the same phase compositions; all are composed of nearly pure Al and pure Si (Figure 7). Given the security consideration, the experiment at a pressure higher than 300 MPa was not performed; moreover, the relative density of the sample prepared at 300 MPa is already able to satisfy production requirements. Thus, a pressure of 300 MPa should be the optimal sintering pressure.

3.1.3. Holding Time

The plastic deformation of Al powders during FHP sintering should necessarily take a certain time; thus, the holding time at sintering temperature would affect the densities of the final products, while a too long holding time is unfavorable to industrial production. Therefore, it is necessary to determine the suitable holding time. Several Al-70Si composite samples were prepared via the FHP technique with a holding time from 0–20 min under a sintering temperature of 470 °C and a sintering pressure of 300 MPa. Due to the rapid heating rate of 100 °C min⁻¹, there are less than 2 min left for the plastic deformation of the Al particles during the heating process. As can be seen in Figure 8, the holding time of 0 min apparently does not provide enough time for the plastic deformation of Al particles. And, with a very short holding time of 5 min, the density has already reached 2.44 g cm⁻³, and the relative density reaches nearly 100 %. It would not show obvious influence on the density of the Ai-70Si composite samples to further extend the holding time, because the holding treatment was designed to allow the continuous phase Al sufficient plastic deformation to encapsulate the dispersed phase Si at a high temperature and pressure. Under the corresponding sintering parameters (470 °C, 300 MPa), the process needed 5 min to be fully realized, at which time the density of the bulk is 2.44 g cm⁻³ (100% relative density, i.e., ideal density). It will not change the physical mixing state of the two phases to continue increasing the holding time, nor will it induce a chemical reaction between the two phases to produce a new phase. Therefore, the density will not change. However, the microscopic morphology of the composites is affected by the holding time (Figure 9). No apparent aggregation of Si particles (given the high melting point of Si) can be seen in the cross-section SEM images for the sample with a holding time of 5 min. With an increase in the holding time, the aggregation of Si particles occurs, which is not beneficial to the overall performance of the Al/Si composite. Thus, 5 min should be the optimal holding time for sintering the Al/Si composite.

To sum up, the optimized FHP sintering parameters for preparing the Al/Si composite are determined to be a sintering temperature of 470 °C, a sintering pressure of 300 MPa and holding time of 5 min. Hence, the rapid heating rate and short holding time ensure that the FHP sintering technique can be applied in large-scale industrial production of Al/Si composites for packaging materials. The samples for the following thermal analyses are all prepared under the above conditions.

3.2. Thermal Properties

The Al/Si composite is intended to be utilized as an electronic package material. Thus, the question of what proportion of Al and Si the thermal conductivity and coefficients of thermal expansion are acceptable should be answered. The Si volume ratios of Al/Si composite are controlled to be 12 vol.%, 27 vol.%, 40 vol.%, 50 vol.% and 70 vol.%, respectively, and the corresponding samples are named Al-12Si, Al-27Si, Al-40Si, Al-50Si and Al-70Si. These samples are all composed of two phases of Al and Si, as shown in the XRD patterns, and the differences in composition are reflected in the intensity of the peaks (Figure 10). As Al and Si form the continuous phase and dispersed phase, respectively, the higher the volume ratio of Al, the smoother the surface of the Al/Si composite samples becomes, as shown in the SEM images (Figure 11). Additionally, if the volume ratio of Si exceeds 50%, an obvious aggregation of Si particles can be observed (Figure 11d,e), which would also influence thermal properties. Thus, the differences in thermal properties are mainly affected by the ratio of Si and Al, rather than phase differences.

In order to satisfy the heat dissipation requirements for future high-performance processors, thermal conductivity is the primary consideration. The thermal conductivities of different Al/Si composite samples decrease as the volume ratio of Si increases (Figure 12). It should be pointed out that the theoretical thermal conductivities of pure Al and Si are 217 W m⁻¹ K⁻¹ and 148 W m⁻¹ K⁻¹, respectively. When the volume ratio of Si exceeds 27 %, the thermal conductivities of the composites are already lower than that of pure Si, which is in the dispersed phase in the Al/Si composite. And the Al-70Si possesses the lowest thermal conductivity of 98.2 W m⁻¹ K⁻¹, less than half that of the thermal conductivity of pure Al. Two main reasons should contribute for the phenomenon: on the one hand, the increase in the volume ratio of Si, with a lower thermal conductivity and coefficient of thermal expansion, would inevitably lead to a decrease in thermal conductivity; on the other hand, the interface between the Al matrix and the Si particles is just formed through the plastic deformation of Al, and the tightly bonded alloy phase should not form at the boundary as described above, which goes against the interfacial thermal transfer and results in a higher interface thermal resistance.

In order to evaluate and predict the thermal conductivities of the Al/Si composites with different compositions for developing package materials with practical value, it is necessary to fit an empirical function between the volume ratio of Si and the thermal conductivity. Generally speaking, the thermal conductivity (k) of a solid–solid binary composite is a function of the thermal conductivity of the continuous phase (k_c), the thermal conductivity of the dispersed phase (k_d), the volume ratio of the dispersed phase (ϕ), the shape and arrangement of the dispersed phase (a), etc. Thus, the thermal conductivity generally has the following form:

(2)$k=k\left(k_c,k_d,\varphi ,a\right)$

As the thermal conductivity is affected by numerous factors, much effort has been paid by many researchers to develop thermal conductivity models suitable for different systems, and to obtain a favorable function for a certain occasion is a complicated process indeed. The Al/Si composite in this work is also a kind of solid–solid binary composite system, and several widely applied theoretical and empirical models are discussed, including the Maxwell model [43,44], the EMT model [44], Chiew–Glandt model [45], the Topper model [46,47] and the Agari model [48,49]. The calculation formulae of the models are summarized in Table 2. As can be seen in Figure 12 and Table 3, the predictions of the Maxwell model, EMT model, the Chiew–Glandt model, and the Topper model are quite close, because the ratio of k_d and k_c (κ) is calculated to be 0.682, relatively close to 1. But these predictions all deviate from the tested value greatly, suggesting that these four models are not suitable for predicting the thermal conductivities of Al/Si composites prepared via FHP sintering. The predictions of these four models are between the thermal conductivities of Al and Si. However, because of the widely distributed interfacial thermal resistance, when the volume ratio of Si exceeds 27%, the thermal conductivities of the composites are already lower than that of pure Si. Thus, the Maxwell model, the EMT model, the Chiew–Glandt model, and the Topper model failed to fit a matched curve based on the tested values. In contrast, the Agari model, with two adjustable parameters, can fit the tested values much better than other models, although the Agari model is generally applied to the systems of polymer–matrix composites. The parameters of C₁ and C₂ are fitted to be 0.995 and 0.829 by least squares method. Thus, the Agari model can be used to predict the thermal conductivities of Al/Si composite samples in a wide ϕ to find the optimized package material.

The coefficient of thermal expansion (CTE) is another important thermal parameter for packaging materials. If the CTEs of packaging materials and substrate materials are not matched, the connection between them might be tortured during repeated thermal cycles, leading to a decline in the heat dissipation capabilities of the processor in its long-term life. The CTE of pure Al is 23.2 × 10⁻⁶ K⁻¹, which is too large to be an appropriate packaging material alone. On the contrary, Si possesses a much smaller CTE of 3.5 × 10⁻⁶ K⁻¹. Thus, since no alloy phase is generated during the FHP sintering process, the CTE is bound to decline by adding a certain amount of Si, as shown in Figure 13. Additionally, the CTE of the Al/Si composite obeys the additivity simply, as shown in Equation (3).

CTE = (1 − ϕ)CTE_Al + ϕCTE_Si(3)

To study the feasibility, reliability and advancement of the FHP technique, a comparison with other researchers’ work on Al/Si composites prepared via the SPS technique is shown in Table 4. The thermal conductivities of Al/Si composites prepared via the FHP technique are comparable with these prepared via the SPS technique with a similar composition, and even higher than some reported values in others’ studies. In the meanwhile, the coefficients of thermal expansion of the samples prepared via the FHP technique and the SPS technique with the same composition are quite close. The phenomena can be attributed to the fact that the reported samples of Al and Si composite system share the same phase constitution with the Al/Si composite in this paper.

To sum up, the thermal conductivity and the coefficient of thermal expansion of the Al/Si composite prepared via the FHP technique are investigated and fitted with the appropriate model, which makes it possible to develop suitable packaging materials of Al/Si composites based on the thermal properties of the substrate materials. A comparison of Al/Si composite systems prepared via SPS and FHP, respectively, shows that FHP is a novel sintering technique which can be compared to SPS. Given its remarkable economy, the FHP technique is bound to be a promising route for preparing Al/Si composites.

4. Conclusions

In this paper, a novel powder sintering technique, FHP, was employed to prepare Al/Si composites with a wide range of Si volume ratios. The technique shows advantages of low costs, ultrahigh heating rates, good reliability and wide usability compared to the SPS technique. Additionally, the FHP oven is self-developed and self-produced. The sintering parameters were determined to be a sintering temperature of 470 °C, a sintering pressure of 300 MPa and a holding time of 5 min, after a series of orthogonal experiments. The relative density of the Al/Si composites can reach nearly 100%, suggesting the advantages of FHP sintering. The thermal performances of the Al/Si composite samples with Si volume ratios of 12 vol.%, 27 vol.%, 40 vol.%, 50 vol.% and 70 vol.% were studied. With an increase in the Si volume ratio, the thermal conductivities and the coefficients of thermal expansion both decrease, due to Si particles’ thermal properties. Furthermore, different thermal conductivity models for solid–solid binary composites were employed to study the heat transfer behavior of Al/Si composites, and the Agari model is matched with the Al/Si system in this paper. The CTE of the Al/Si composites obey additivity simply. Numeric modeling would help develop the required packaging materials based on the thermal performances of the substrate materials, like Si or GaAs semiconductor devices. A side-by-side comparison between the FHP sintering method and the conventional SPS method was performed for verification of the higher thermal conductivity and thermal expansion coefficient of the samples prepared by the FHP sintering method. For example, the thermal conductivity of the Al-40Si composites sintered by the FHP method is higher than that of the conventional SPS method (139 to 107 W m⁻¹ K⁻¹). These thermal performances of Al/Si composites are comparable with other Al/Si composites prepared by SPS methods. Given the economy of the FHP technique, it shows great potential for developing and producing Al matrix packaging materials via powder metallurgy sintering in the future.

Footnotes

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Scheme 1. The FHP-828 oven and a scheme of the core part of the FHP oven.

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Figure 1. Photograph of an Al/Si composite disk sample with 70 vol.% Si.

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Figure 2. Influences of sintering temperature on density and relative density of Al-70Si composite samples. (The sintering pressure: 300 MPa, holding time: 5 min).

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Figure 3. XRD patterns of Al-70Si composite samples prepared at sintering temperatures of 460 °C, 470 °C, 475 °C. (Sintering pressure: 300 MPa, holding time: 5 min).

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Figure 4. SEM images of Al-70Si composite samples prepared at sintering temperature of (a,d) 450 °C, (b,e) 460 °C, (c,f) 470 °C with different magnifications. (The sintering pressure: 300 MPa, holding time: 5 min. Cracks are marked with red circles).

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Figure 5. Influences of sintering pressure on density and relative density of Al-70Si composite samples. (The sintering temperature: 470 °C, holding time: 5 min).

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Figure 6. SEM images of Al-70Si composite samples prepared at sintering pressures of (a) 100 MPa, (b) 150 MPa, (c) 200 MPa, (d) 250 MPa, (e) 300 MPa. (The sintering temperature: 470 °C, holding time: 5 min. Cracks are marked with red circles).

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Figure 7. XRD patterns of Al-70Si composite samples prepared at different sintering pressure of 460 °C, 470 °C, 475 °C. (The sintering pressure: 300 MPa, holding time: 5 min).

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Figure 8. Influences of holding time on density and relative density of Al-70Si composite samples. (The sintering temperature: 470 °C, sintering pressure: 300 MPa).

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Figure 9. SEM images of Al-70Si composite samples prepared with holding time of (a) 5 min, (b) 10 min, (c) 20 min. (The sintering temperature: 470 °C, sintering pressure: 300 MPa).

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Figure 10. XRD patterns of Al-12Si, Al-27Si, Al-40Si, Al-50Si, Al-70Si.

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Figure 11. SEM images of (a) Al-12Si, (b) Al-27Si, (c) Al-40Si, (d) Al-50Si, (e) Al-70Si.

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Figure 12. Thermal conductivities of different Al/Si composites.

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Figure 13. Coefficient of thermal expansion of different Al/Si composites.

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