Water stress corrosion at wafer bonding interface during bond strength evaluation
Tomoya Iwata, Junya Fuse, Yuki Yoshihara, Yusuke Kondo, Marie Sano, Fumihiro Inoue
Abstract
Wafer-to-wafer bonding is becoming a critical unit process step with the increase in the demand for 3D integration. The widely used bonding method is plasma activated bonding, where it is essential to ensure sufficient bond strength to withstand the stresses generated during subsequent processes and achieve multi-layer stacking or layer transfer. Although the double cantilever beam method is widely used to evaluate wafer bond strength, significant variation occurs due to water stress corrosion at the bonding interface. These factors have not been adequately addressed, and precise measurement conditions have yet to be established. In this study, a semi-auto tool was introduced to conduct measurements under an inert atmosphere, whereby the influence of water stress corrosion was eliminated. Furthermore, the study elucidated the effects of the crystal orientation and blade insertion conditions. The impacts of interfacial voids and the annealing conditions on bond strength were revealed. Observation of the progress of delamination during measurements under an inert atmosphere enabled the effective estimation of the moisture content that remained inside the wafers, which then contributed to the selection of appropriate annealing conditions. • Accurate bond strength via Double Cantilever beam method for direct wafer bonding was investigated. • Controlled environment ensured consistent measurements with minimal variation by eliminating water stress corrosion. • Water stress corrosion is caused by moisture in the atmosphere, interface voids, and residual moisture, affecting delamination length. • Evaluating delamination under inert atmosphere aids in estimating proper annealing conditions.