Paper Infomation
Development and Performance Study of High-Performance Electronic Packaging Materials
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Author: Shenglan Fang
Abstract: As electronic devices continue to evolve toward higher power densities, faster speeds, and smaller form factors, the demand for high-performance electronic packaging materials has become increasingly critical. These materials serve as the physical and functional interface between semiconductor components and their operating environment, impacting the overall reliability, thermal management, mechanical protection, and electrical performance of modern electronic systems. This study investigates the development, formulation, and performance evaluation of advanced packaging materials, focusing on polymer-based composites, metal and ceramic matrix systems, and nanomaterial-enhanced formulations. A comprehensive analysis of key performance metrics—including thermal conductivity, electrical insulation, mechanical robustness, and environmental resistance—is presented, alongside strategies for material optimization through interface engineering and processing innovations. Furthermore, the study explores cutting-edge integration technologies such as 3D packaging compatibility, low-temperature co-firing, and high-density interconnects. The findings provide critical insights into the structure-property-processing relationships that define the effectiveness of next-generation packaging materials and offer a roadmap for material selection and system integration in high-reliability electronic applications.
Keywords: Electronic Packaging Materials, Thermal Interface Materials, High-Performance Composites, Nanomaterials, Thermal Conductivity, 3D Packaging, Reliability, Polymer Composites, Dielectric Properties, Microfabrication
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