Silicon-Interconnect Fabric for Fine-Pitch (≤10 μm) Heterogeneous Integration
SivaChandra Jangam, Subramanian S. Iyer
Abstract
The apparent saturation of aggressive Moore's law scaling of semiconductor technologies is pushing the boundaries of traditional packaging and integration schemes to accommodate the ever-growing data bandwidth and heterogeneity demands. In this article, we demonstrate the silicon-interconnect fabric (Si-IF) technology as a superior alternative to conventional printed circuit boards (PCBs) to enhance system scaling. The Si-IF is a silicon-based, package-less, fine-pitch, highly scalable, heterogeneous integration platform to assemble and integrate massive wafer-scale systems. In this technology, dielets are closely assembled on the Si-IF at small interdielet spacings ( ≤ 50 μm) using fine-pitch ( ≤ 10 μm) die-to-substrate interconnects allowing for tight integration on a system-level package. To achieve these fine-pitch interconnects, a novel assembly technique using solder-less direct metal-metal [copper-copper (Cu-Cu)] thermal compression bonding was developed. Using this process, sub-10- μm-pitch interconnects with a low specific contact resistance of ≤ 0.7 Ω·μm <sup xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink"> 2</sup> and high shear force of 90 N for 4-mm <sup xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">2</sup> dies were successfully demonstrated. Moreover, these fine-pitch interconnects combined with the small interdie spacing provide a large number of parallel short links ( ≤ 500 μm) with low loss (≤2 dB) for interdielet communication that is comparable to on-chip connections. Consequently, simple buffers can transfer data between dies using a Simple Universal Parallel intERface for chips (SuperCHIPS) protocol at low link latency (<; 20 ps), low energy per bit (≤0.03 pJ/b), and high data rates (up to 10 Gb/s/link), corresponding to an aggregate data bandwidth of up to 8 Tb/s/mm. The benefits of the SuperCHIPS interface are experimentally demonstrated using functional dielet assembly on the Si-IF to show 4- 23× higher data bandwidth, 3- 65× lower latency, and 5- 40× lower energy per bit compared to existing integration schemes.