Computer chips that transmit data with light instead of electricity consume
much less power than conventional chips, but so far, they've remained laboratory
curiosities. Professors Vladimir Stojanovic and Rajeev Ram and their colleagues
in MIT's Research Laboratory
of Electronics and Microsystems Technology Laboratory hope to change that, by
designing optical chips that can be built using ordinary chip-manufacturing
processes.
 | | In the prototype optical chip shown here, the circles in the top two rows are "ring resonators" that can filter out light of different wavelengths. Image courtesy of Vladimir Stojanovic |
“I don't see anyone else that's doing that,” says Michael
Watts, a researcher at Sandia National Laboratories who's also working
on optical chips. “If they're successful at that, then convincing
a major processor or memory manufacturer that this is a viable approach will
be much, much easier.”
Granted access to the same manufacturing facilities that Texas Instruments
uses to produce cell phone chips and microprocessors, the MIT researchers have
demonstrated that they can put large numbers of working optical components and
electronics on the same chip. But so far, the electronics haven't been
able to control the optics directly. That's something that Stojanovic
hopes to show with a new batch of chips due back from TI and another major semiconductor
manufacturer this winter.
Optical data transmission could solve what will soon be a pressing problem
in chip design. As chips' computational capacity increases, they need
higher-bandwidth connections to send data to memory; otherwise, their added
processing power is wasted. But sending more data over an electrical connection
requires more power.
Smaller transistors are more energy-efficient than larger ones, so over time,
chips' total power consumption has changed little. But “the fraction
of power that's used for communications has grown,” Watts says.
“At some point, you have to devote all your power to communications. And
that point's not too far off. And then what's left for computation?
Nothing.” Future chips could simply draw more power, but then they would
also be harder to cool, and the battery life of laptops and handheld devices
would dramatically shorten.
So chip companies would welcome a more energy-efficient way to move data around
— if they were confident that it was cost-effective. And that's
why demonstrating compatibility with existing manufacturing processes would
be so persuasive.
Manufacturers build chips by sequentially depositing layers of different materials
— like silicon, silicon dioxide, and copper — on a wafer of silicon,
and then etching the layers away to build three-dimensional structures. The
problem with using existing processes to build optical components is that the
deposition layers are thinner than would be ideal. “You would want a normal
photonic device to be a little bit taller and thinner so that you can minimize
the surface-roughness losses,” Stojanovic says. “Here you don't
have that choice because the film thicknesses are set by fabrication.”
Optical chips use structures called waveguides to direct light, and researchers
trying to add optical components to a silicon chip usually carve the waveguides
out of a single crystal of silicon, Stojanovic says. But waveguides made from
single-crystal silicon require insulating layers above and below them, which
standard chip-manufacturing processes like TI's and Intel's provide
no way to deposit. They do, however, provide a way to deposit insulators above
and below layers of polysilicon, which consists of tiny, distinct crystals of
silicon clumped together and is typically used in the part of a transistor called
the gate. So the MIT researchers built their waveguides from polysilicon instead.
So far, TI has produced two sets of prototypes for the MIT researchers, one
using a process that can etch chip features as small as 65 nanometers, the other
using a 32-nanometer process. To keep light from leaking out of the polysilicon
waveguides, the researchers hollowed out the spaces under them when they got
the chips back — the sole manufacturing step that wasn't possible
using TI's in-house processes. But “that can probably be fixed more
elegantly in the fabrication house if they see that by fixing that, we get all
these benefits,” Watts says. “That's a pretty minor modification,
I think.”
The MIT researchers' design uses light provided by an off-chip laser.
But in addition to guiding the beam, the chip has to be able to load information
onto it and pull information off of it. Both procedures use ring resonators,
tiny rings of silicon carved into the chip that pull light of a particular frequency
out of the waveguide. Rapidly activating and deactivating the resonators effectively
turns the light signal on and off, and bursts of light and the gaps between
them can represent the ones and zeroes of digital information.
To meet the bandwidth demands of next-generation chips, however, the waveguides
will have to carry 128 different wavelengths of light, each encoded with its
own data. So at the receiving end, the ring resonators provide a bank of filters
to disentangle the incoming signals. On the prototype chips, the performance
of the filter banks was “the most amazing result to us,” Stojanovic
says, “which kind of said that, okay, there's still hope, and we
should keep doing this.” The wavelength of light that the resonators filter
is determined by the size of their rings, and no one — at either TI or
MIT — could be sure that conventional manufacturing processes were precise
enough to handle such tiny variations.
Stojanovic hopes that the next batch of prototypes, which should give the chips'
electronics control over the optical components, will demonstrate that the resonators
perform as well when loading data onto light beams. At the same time, the team
is looking to extend its approach to memory chips. “The memory's
a much tougher nut to crack, because it is such a cost-driven business, where
every process step matters,” Stojanovic says. “Things are a lot
harder to change there, and optics really needs to be absolutely compatible
with process flow.” But if memory chips as well as processors sent data
optically, Stojanovic says, then in addition to saving power, they could make
computers much faster. “If you just focus on the processor itself, you
maybe get a 4x advantage with photonics,” Stojanovic says. “But
if you focus on the whole connectivity problem, we're talking 10, 20x
improvements in system performance.”
Posted November 23rd, 2009
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