Optical interconnect technology is widely applied as active optical cables for rack-to-rack links in datacenters for cloud-computing, big data, analytics and high-performance computing. Transceivers with a single mode silicon photonics electro-optical subassembly are emerging as an alternative to vertical-cavity surface-emitting laser (VCSEL) based multimode optical links. The longer distance of single mode interconnects and the ability to integrate optical functions such as wavelength division multiplexing and coherent transmission drive this trend. While silicon photonics (SiP) integrates passive optical functions, it lacks a solution for a fully CMOS compatible integrated laser source. Consequently, today’s commercial SiP-based transceiver subassemblies consist of at least three discrete chips; a passive SiP chip, a laser and a (Bi)CMOS chip. These components are then aligned and assembled into a three dimensional stack. The cost of the components and the assembly procedure are a big challenge. The laser takes a substantial part of the bill of materials and the packaging cost of SiP transceivers represents more than 60% of the total manufacturing expense. Furthermore, this discrete approach lacks design flexibility and functionality features that are required to further scale the performance and density of optical interconnects for future computing systems.
DIMENSION establishes a truly integrated electro-optical platform, extending the silicon (Bi)CMOS and SiP platform with III-V photonic functionality. The III-V integration concept is fully CMOS compatible and offers fundamental advantages compared to state-of-the art integration approaches. After bonding and growing ultra-thin III-V structures onto the silicon front-end-of-line, the active optical functions are embedded in between the front-end and back-end of line. This offers great opportunities for new innovative devices and functions at the chip-level but also for the assembly of such silicon devices. As processing takes place on silicon wafers, this project has the unique opportunity to bring the cost of integrated devices, with CMOS, photonic and III-V functionality, down to the cost of silicon volume manufacturing. Such a platform has the potential to allow Europe to take a leading position in the field of high functionality integrated photonics. The project demonstrators adhere to optical components and low-power electronics, which will show that a monolithic CMOS-compatible integration process of active optical III-V components together with SiP and electrical circuits is possible. Such a ground-breaking integration technology opens a viable route towards ultra-low-cost high-performance optical transceivers for a new era of datacenters and cloud systems.
In conclusion, we have shown the principle CMOS-compatible integration technology of active III-V devices on Si BiCMOS. Using a limited BEOL, LED structures with luminescence were functional, but the full BiCMOS BEOL could not be finished to validate III-V embedding structures in (Bi)CMOS BEOL for short and fast electrical interconnects to the electrical devices. Also electrically pumped III-V on Si lasing at room temperature remains unsolved. However, many challenges to realize the new integration technology have been resolved and many building block have been investigated, realized and demonstrated, which include for example: the bonding and direct growth of ultra-thin III-V QW stacks on FEOL BiCMOS, efficient optical coupling between Si and III-V via a-Si waveguides and based on adiabatic mode conversion, laser feedback and passive optical structures in Si for minimum processing requirements on the III-V structure, CMOS-compatible contacts, and various current confinement and injection schemes.
Moreover, we have designed and verified many EPIC chips, like co-integrated drivers with modulators and photodetectors with transimpedance amplifiers, with improved performance. For the packaging of sub-assemblies and transceiver systems, improved and optimized techniques for wirebonding, optical alignment and optical coupling with high precision and low losses have been developed and applied. The EPIC designs and sub-assemblies have been successfully measured. All the project results have been intensively disseminated and will be exploited after the project end.