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Aluminum silicon carbide provides thermal
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Aluminum silicon carbide provides thermal management solutions for electronic packaging
Designing low-cost, highly reliable microwave electronics, microelectronics, optoelectronics, and power semiconductor systems using state-of-the-art materials is impractical. To ensure the reliability of such devices, electronic packaging and substrate thermal management solutions are required, so engineers need materials that can provide thermal management characteristics while achieving optimal power density in smaller designs. Cost-effective production of such materials requires robust molding processes that meet the functional requirements of the package design.Get more news about Electronic Packaging Silicon Aluminum Alloy,you can vist our website!
Aluminum silicon carbide (AlSiC) metal matrix composites provide a highly reliable and cost effective thermal management solution for electronic packaging. It offers high thermal conductivity (~200 W/mK) and a tunable low coefficient of thermal expansion (CTE). The low density, high strength and stiffness of AlSiC give it advantages over traditional high-density materials for applications that require weight reduction and need to withstand shock and vibration.AlSiC can be manufactured in net-shape or near-net-shape at low cost. Examples of net-shape or near-net-shape fabricated AlSiC products are shown in Figure 1. In addition, the AlSiC forming process allows for economical integration with high heat dissipation materials such as diamond and high thermal conductivity graphite, making it ideal for applications requiring high heat dissipation capabilities. Because AlSiC provides the required thermal stability and temperature uniformity requirements. In addition, it is a preferred material for high-power transistors and insulated gate bipolar transistors (IGBTs), providing good thermal cycling reliability.
As a unique manufacturing process, AlSiC first produces porous, low-CTE silicon carbide (SiC) particles and then dissolves and infiltrates high-CTE aluminum metal into the mold. The AlSiC manufacturing process is cost effective because both the preform and the infiltrated mold cavity can be designed to match the end product shape. As a result, the cast composite product requires no further processing (net-shape manufacturing) or very little processing (near-net-shape manufacturing).AlSiC thermal conductivity values range from 180 W/m/K to 200 W/m/K, depending on the SiC/Al ratio.
AlSiC materials are primarily used for flip chip lids. AlSiC is an ideal material for this application because its CTE is compatible with dielectric substrates, ceramic ball arrays (BGAs), low temperature sintered ceramic (LTCC) materials, and printed circuit boards, and also has high thermal conductivity values (refer to Table 1 for AlSiC material grades corresponding to specific systems and component types). At the same time, the high strength and stiffness of AlSiC also provide protection for IC devices during the assembly process. The low density of these materials also improves reliability when the device is subjected to shock or vibration. For example, in highly automated assembly machines, where high-speed acceleration and deceleration movements between different step operations can cause inertial shocks and vibrations, utilizing AlSiC products can increase throughput.
AlSiC can be fabricated with complex profiles, thus enabling the manufacture of complex flip-chip packages at low cost. Figure 3 shows an example of a product profile with multiple cavities to accommodate electronics, pillars to provide IC device connections, holes for material fill, and different flange designs. the surface of AlSiC castings also supports different marking methods including laser marking, paint, ink, and screen printing, as well as electroplating, anodizing, and other surface metal treatments suitable for aluminum.
The geometric profile of an optoelectronic package is more complex than that of a flip-chip cover, and therefore requires more precise dimensional control for the optically aligned pattern. Figure 4 is an example of an AlSiC optoelectronic package. All packages in the figure are die-cast, and no additional machining is required for the critical optical alignment part. Therefore the cost is lower compared to conventional packages.
Thermal management in optoelectronic devices is also very important. Devices typically operate near room temperature, which requires materials with good thermal performance to maintain temperature uniformity and optimize cooler performance. adjustable matched CTE values for AlSiC ensure alignment of sensitive optics during operation, while also eliminating residual stresses that may be introduced during soldering or brazing assembly.