Title :
Multichip packaging technology with laser-patterned interconnects
Author :
Barfknecht, Andrew T. ; Tuckerman, David B. ; Kaschmitter, James L. ; McWilliams, Bruce M.
fDate :
12/1/1989 12:00:00 AM
Abstract :
A multichip silicon-on-silicon packaging technology has been developed which incorporates laser-patterned thin-film interconnects. This technology is particularly suited for application in high-speed, high-power, and high-I/O systems, where its unique characteristics provide many advantages over more traditional methods. The laser-patterned thin-film interconnects allow higher I/O densities and better electrical performance than wire bonds or TAB (tape automated bonding). The face-up, thin-film eutectic die attach technique used provides much lower thermal resistance between the substrate and the chips than can be achieved with solder bump die attach. In addition, laser-patterned interconnects demonstrate superior ruggedness and fatigue resistance under thermomechanical cycling and shock. This technology has been used to produce a ten-chip memory module, samples of which have been subjected to testing by means of relevant methods of MIL-STD 883C
Keywords :
laser beam machining; modules; packaging; thermal resistance; I/O densities; MIL-STD 883C; Si-Si; electrical performance; fatigue resistance; high speed-systems; high-I/O systems; high-power systems; laser-patterned thin-film interconnects; multichip silicon-on-silicon packaging technology; solder bump die attach; tape automated bonding; ten-chip memory module; thermal resistance; thermomechanical cycling; thermomechanical shock; thin-film eutectic die attach technique; wire bonds; Bonding; Electric resistance; Fatigue; Microassembly; Packaging; Semiconductor thin films; Substrates; Thermal resistance; Transistors; Wire;
Journal_Title :
Components, Hybrids, and Manufacturing Technology, IEEE Transactions on
