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3D integration approaches for MEMS and CMOS sensors based on a Cu through-silicon-via technology and wafer level bonding

: Hofmann, L.; Dempwolf, S.; Reuter, D.; Ecke, R.; Gottfried, K.; Schulz, S.E.; Knechtel, R.; Geßner, T.


Sánchez-Rojas, José Luis (Hrsg.) ; Society of Photo-Optical Instrumentation Engineers -SPIE-, Bellingham/Wash.:
Smart Sensors, Actuators, and MEMS VII; and Cyber Physical Systems : Barcelona, Spain, 4 - 6 May 2015
Bellingham, WA: SPIE, 2015 (Proceedings of SPIE 9517)
ISBN: 978-1-62841-639-8
Paper 951709, 12 S.
Conference "Smart Sensors, Actuators, and MEMS" <7, 2015, Barcelona>
Conference "Cyber Physical Systems" <2015, Barcelona>
Fraunhofer ENAS ()

Technologies for the 3D integration are described within this paper with respect to devices that have to retain a specific minimum wafer thickness for handling purposes (CMOS) and integrity of mechanical elements (MEMS). This implies Through-Silicon Vias (TSVs) with large dimensions and high aspect ratios (HAR). Moreover, as a main objective, the aspired TSV technology had to be universal and scalable with the designated utilization in a MEMS/CMOS foundry. Two TSV approaches are investigated and discussed, in which the TSVs were fabricated either before or after wafer thinning. One distinctive feature is an incomplete TSV Cu-filling, which avoids long processing and complex process control, while minimizing the thermomechanical stress between Cu and Si and related adverse effects in the device. However, the incomplete filling also includes various challenges regarding process integration. A method based on pattern plating is described, in which TSVs are metalized at the same time as the redistribution layer and which eliminates the need for additional planarization and patterning steps. For MEMS, the realization of a protective hermetically sealed capping is crucial, which is addressed in this paper by glass frit wafer level bonding and is discussed for hermetic sealing of MEMS inertial sensors. The TSV based 3D integration technologies are demonstrated on CMOS like test vehicle and on a MEMS device fabricated in Air Gap Insulated Microstructure (AIM) technology.