Die-embedded packaging using Corning® multi-layered glass

Die-embedded (DE) packaging technologies in recent years have ventured into advanced packaging structures, such as fan-out wafer level packages (FOWLPs) or package-on-packages (PoPs). They offer higher density at lower costs, despite many challenges, such as the die-shift and warpage problems often observed during the molding process, caused by the high shrinkage and high coefficients of thermal expansion (CTEs) of the molding materials. This in turn makes it difficult to accurately mount the high-density fine-pitch bumps and adversely affects the overall yield, especially in processes using large-size substrates. Glass, known for its superior dimensional and thermal stability and its low or tunable CTEs, can be advantageous in reducing die-shift and warpages as opposed to other alternative material solutions for the molding process. In this paper, we propose a packaging solution based on a glass substrate incorporating a plurality of precisely dimensioned cavities, with a chip positioned in each cavity to prevent them from shifting during processing. Corning® Adaptive Formed Glass (AFG), a laminate glass with a unique clad/core/clad structure, allows for effectively forming cavities with high dimensional precision and positional accuracies as well as surface flatness through a wet etch process. Using a 0.5mm thick laminate Corning® AFG glass, we successfully designed and fabricated three types of DE packages with lab scale tools at Korea Electronics Technology Institute (KETI): single- and double-sided DE packages, and package-on-packages (POPs). High etching selectivity over 20:1, which was achieved by carefully designing the core and clad glass compositions, enabled a wet-etch cavity forming process with accurate cavity depths and flat bottom surfaces (< ± 2.5μm) with relative ease. A double-sided DE package with a total thickness of 600μm was fabricated with two 125μm-thick IC chips, one embedded on each side of the substrate, and connected by metallized through glass vias (TGVs). A POP measured at 5.1×5.1×1.27 mm3 was also successfully demonstrated by using two built-in double-sided DE packages joined by flip-chip bonding, equivalent to stacking four layers of conventional single-sided DE packages. The double-sided DE packages and POPs presented in this paper are believed to be the world’s first demonstration on glass. The work also manifests the immense potential of Corning® AFG glass in enabling higher density IC packaging and large-size panel-level (or wafer-level) packaging.