When the subject of hybrid bonding is brought up in the industry, the focus is often on how this technique is used to manufacture CMOS image sensors (CIS), an essential device for today’s digital cameras, particularly those found in smartphones. As such, CIS is a common touchpoint given the ubiquity of mobile phones, whether you hold a product from Apple, Samsung or Huawei in your hands.
But while today’s CIS devices currently dominate the use of hybrid bonding, high-performance computing (HPC) is emerging as a new high-growth application for hybrid bonding. This is a result of the trend toward finer pitched interconnects in advanced 3D packaged memory technologies. In addition, the market share of high-end performance packaging, including both 2.5D and 3D packaging, is expected to be $7.87B by 2027, with a compound annual growth rate (CAGR) of 19% from 2021 to 2027, according to Yole Développement. As for 3D stacked packaging alone, it is expected to grow at a CAGR of 58% to 70% during the same period.
Using direct Cu-to-Cu connections instead of bumps and suitable for pitches less than 10μm, hybrid bonding often involves the direct stacking of two wafers, with the space between the two planarized surfaces approaching zero. Hybrid bonding has advantages over conventional micro-bumping, such as enabling smaller dimension I/O terminals and reducing pitch interconnects. But while both hybrid bonding and conventional micro-bumping support higher-density interconnect schemes, hybrid bonding is an expensive process compared to bumping and requires much tighter process control, especially in the areas of defect inspection, planarity measurement and void detection.
While wafer-to-wafer bonding has already been demonstrated for NAND devices and is currently used in CIS manufacturing for the integration of the imager layer and logic, DRAM manufacturers are also looking to adapt hybrid bonding to replace bumps. Utilizing a hybrid bonding interconnect scheme capable of reducing the overall package thickness by tens and possibly hundreds of microns in certain situations, HBM (high-bandwidth memory) die are vertically stacked in 4,8,12,16 die stacks. The gap between each die is about 30μm when bumps are used, but the gap is nearly zero with hybrid bonding.