Organic molecules give silicon circuitry all-optical switching capability.
The next time an overnight snow begins to fall, take two bricks and place them side by side a few inches apart in your yard. In the morning, the bricks will be covered with snow and barely discernible. The snowflakes will have filled every vacant space between and around the two bricks.
What you will see, says Ivan Biaggio, resembles a phenomenon that, when it occurs at the smallest of scales on an integrated optical circuit, could hasten the day when the Internet works at superfast speeds.
Biaggio, an associate professor of physics, is part of an international team of scientists and engineers who have developed an organic material with an unprecedented combination of high optical quality and the strong ability to mediate light-to-light interaction. The researchers have integrated this material with silicon technology so it can be used in optical telecommunication devices. They reported their findings recently in Nature Photonics.
The new material is composed of small organic molecules with high nonlinear optical susceptibilities. It mimics the behavior of the snowflakes covering the bricks when it is deposited into the slot, or gap, that separates the silicon waveguides that control the propagation of light beams on an integrated optical circuit.
Just as the snowflakes, being tiny and mobile, fill every empty space between the two bricks, Biaggio says, the molecules completely and homogeneously fill the slot between the waveguides. The slot is tens of nanometers wide.
“We have been able to make thin films by combining the molecules into a material that is perfectly transparent and flat, and free of any irregularities that would affect optical properties,” says Biaggio.
The slot between the waveguides is the region where most of the light guided by the silicon propagates. By filling the slot, say Biaggio and his collaborators, the molecules add an ultrafast all-optical switching capability to silicon circuitry, creating a new ability to perform the light-to-light interactions necessary for data processing in all-optical networks.
The nanophotonic device that is obtained in this way, says the group, has demonstrated the best all-optical demultiplexing rate yet recorded for a silicon-organic-hybrid (SOH) device. In tests, the novel hybrid device was able to extract every fourth bit of a 170.8-gigabit-per-second telecommunications data stream and to demultiplex the stream to 42.7 gigabits per second.
Biaggio collaborates with researchers from the Institute of Photonics and Quantum Electronics at the University of Karlsruhe in Germany, the Photonics Research Group at Ghent University in Belgium, and the Laboratory for Organic Chemistry at the Swiss Federal Institute of Technology (ETH) in Zurich. Biaggio is affiliated with Lehigh’s Center for Optical Technologies (COT). Another group member, Bweh Esembeson, earned a Ph.D. in physics from Lehigh and is now an applications engineer with Thorlabs Inc. in New Jersey.
A nonlinear optical answer to bandwidth demand
As Internet users demand greater bandwidth for faster communications, scientists and engineers are working to increase the speed at which information can be transmitted and routed along a network. They are hoping to achieve a major leap in velocity by designing circuits that rely solely on light waves to process data.
|By homogeneously filling the slot separating the silicon waveguides, the new material adds an ultrafast all-optical switching capability to silicon circuitry.|
At present, data must be converted back and forth from optical signals to electrical signals in order to manage its progress within an optical telecommunication network. This limits the flexibility and speed of optical telecommunication. All-optical circuits, experts say, could unleash the full potential of optical telecommunication and data processing.
All-optical circuits require nonlinear optical materials with high optical properties. A nonlinear optical response occurs in a material when the intensity of light alters the properties of the material through which light is passing, affecting, in turn, the manner in which the light propagates.
Biaggio’s group is working with an organic molecule called DDMEBT that possesses one of the strongest nonlinear optical responses yet observed for its relatively small size. The molecule can condense from the vapor phase into a bulk material. The high, off-resonant bulk nonlinearity and large-scale homogeneity of this material, says Esembeson, represent a unique combination not often found in an organic material.
The DDMEBT bulk material possess 1,000 times the nonlinearity of silicon, but is difficult to flexibly structure into nanoscale waveguides or other optical circuitry. Silicon, on the other hand, is structurally suited to the dense integration of components on photonic circuit devices. And silicon technology is mature and precise. It enables the creation of waveguides whose nanoscale flatness facilitates the control of light propagation.
“With pure silicon,” says Biaggio, “you can build waveguides that enable you to control light beam propagation, but you cannot get ultrafast light-to-light interaction. Using only silicon, people have achieved a data switching rate of only 20 to 30 gigabits per second, and this is very slow.
“We need higher-speed switching to achieve a higher bit rate. Organic materials can do this, but they are not terribly good for building waveguides that control propagation of tightly confined light beams.”
The best of both worlds
To combine the strengths of the DDMEBT and the silicon, Biaggio’s group has fashioned SOH waveguides in which the silicon waveguide are covered with DDMEBT.
“We start with a silicon waveguide designed to guide the light between two silicon ridges,” he says. “Then we use molecular beam deposition to fill the space between the ridges with the organic material, DDMEBT. This creates a dense plastic with high optical quality and high nonlinearity.
“We combine the best of both methods.”
One of the group’s singular achievements, he says, is the filling-in process.
“The key question is whether we can put the DDMEBT between the two silicon strips. There is a lot of research in this area, but no one has yet been able to make an organic material completely and homogeneously cover such a silicon structure so that it spreads out and fills all the spaces. Homogeneity is necessary to prevent light scattering and losses.
“We achieved this by using a molecular structure that decreases intermolecular interactions and promotes the formation of an homogeneous solid state. We then heated the molecules to a vapor phase and used a molecular beam to deposit the molecules on top of the silicon structure. The molecules were able to homogeneously fill the nanoscale slot between the silicon ridges and to cover the whole structure we needed to cover.
“Our collaborators in Karlsruhe were able to reliably switch individual bits out of a 170.8-gigabit-per-second data stream. This is impressive, but the organic material would be able to support even faster data rates.”