Abstract
Advanced wafer-level packaging (WLP) techniques, mainly driven by high performance applications in memory and mobile market, have been adopted for large-scale manufacturing in recent years. Temporary wafer bonding and debonding technology has been widely studied and developed over the last decade for use in various WLP technologies, such as package-on-package (PoP), fan-out integration, and 2.5-D and 3-D integration using through-silicon-via (TSV). Temporary bonding technology enables handling of thinned substrates (<100 μm), which can no longer self-support during backside processing and packaging. Moreover, some applications require the temporary bonding materials to withstand temperatures up to 250°C in high-vacuum conditions, and even up to 350°C or higher during the dopant activation step required for manufacturing power devices. Therefore, a simple yet effective temporary bonding process and material that can survive all the backside processes is highly desired.
In this study, a series of formulations based on polar thermoplastics were developed for temporary wafer bonding applications. These materials target high temperature survivability and improved adhesion to prevent the premature delamination during downstream wafer processing. All of these materials provide high thermal stability up to 250°C or higher, and are able to be bonded to carrier wafers treated with release layers, which can be selectively debonded by either mechanical or laser release after backside processing. The material left on device wafer after debonding can be easily cleaned using common industrial solvents. Wafers bonded with these materials demonstrate lower overall stack total thickness variation (TTV < 5 μm) after grinding and have successfully passed a 200°C PECVD process without any delamination during grinding and PECVD processes.
Large-Scale Coaxial Magnetron Discharge Containing Magnets at Extremely High Vacuum and Its Application to Sputter Ion Pump.