Merging materials key to SoC optical success

That means the would-be SoC for optical networks will have to merge different types of materials. And as of today, there's no convenient way to do that. " The fundamental problem is that GaAs and InP have a different lattice constant than silicon. To really solve the problem, you have to almost engineer the lattice of the silicon," said George Ugras, general partner with Adams Capital Management (Palo Alto, Calif.).

Still, there's an ongoing push to develop the monolithic integration that would combine silicon and III-V materials. Some early startups on this path have succumbed to the recession, but others continue to pop up. For example, Ugras' firm has funded AmberWave Systems Corp. (Salem, Mass.), which is investigating ways to alter the lattice structure of strained silicon.

Elsewhere, researchers are pursuing quantum-well techniques, as explained in a contribution by Craig Hamilton and John Marsh of Intense Photonics Ltd. (High Blantyre, Scotland). Their article discusses quantum-well intermixing, which can be used to craft two-dimensional structures such as multiplexers and demultiplexers. Another startup exploring quantum-well technique s is DenseLight Semiconductors Pte. Ltd., which is fashioning optical components out of InP.

But for more-established companies, monolithic integration is too immature to be practical, particularly considering the cost of developing the proper technology. "You need to be pretty sure that the product is going to be a high enough runner to get your money back," said Mathew Arcoleo, a senior marketing manager with Cypress Semiconductor Corp. (San Jose, Calif.).

One pragmatic alternative is hybrid integration, which uses flip-chip techniques to build optoelectronic modules. Here, silicon-based elements, such as driver electronics for the laser, are built as a normal semiconductor. The nonsilicon elements such as the laser itself are then bonded onto the silicon with ordinary flip-chip technology.

Bookham Technology Ltd. (Abingdon, England) made this kind of integration a key to its ASOC dev ices, in which passive elements are etched onto the silicon-on-insulator devices but active photonics such as lasers are bonded on separately. Hybrid integration on ordinary SiGe is a possibility too, as Axel Reisinger and Mani Sundaram of TeraConnect Inc. (Nashua, N.H.) discuss in their article.

A literal SoC for optoelectronics may remain forever out of reach, because it may never be possible to integrate lithium niobate (LiNO3)-a choice material for laser modulators-with silicon. But researchers are showing that monolithic integration holds some promise for simplifying optical-networking systems of the future, and hybrid integration appears to be a satisfactory alternative for the here-and-now. "If you can build a 'module' and get it down to two or three ICs, that's still a step in the right direction," said Marc Hartranft, business unit director of Cypress' optics division.