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Topic Name: New material could lead to faster chips : Graphene may solve communications speed limit
Category: Nanocharacterization
Research persons: Jing Kong,Tomás Palacios
Location: Cambridge, United States
Details
New research findings at MIT could lead to microchips that operate at much
higher speeds than is possible with today's standard silicon chips, leading to
cell phones and other communications systems that can transmit data much faster.
The key to the superfast chips is the use of a material called graphene, a
form of pure carbon that was first identified in 2004. Researchers at other
institutions have already used the one-atom-thick layer of carbon atoms to make
prototype transistors and other simple devices, but the latest MIT results could
open up a range of new applications.
The MIT researchers built an experimental graphene chip known as a frequency
multiplier, meaning it is capable of taking an incoming electrical signal of a
certain frequency -- for example, the clock speed that determines how fast a
computer chip can carry out its computations -- and producing an output signal
that is a multiple of that frequency. In this case, the MIT graphene chip can
double the frequency of an electromagnetic signal.
Frequency multipliers are widely used in radio communications and other
applications. But existing systems require multiple components, produce "noisy"
signals that require filtering and consume large power, whereas the new graphene
system has just a single transistor and produces, in a highly efficient manner,
a clean output that needs no filtering.
The findings are being reported in a paper in the May issue of Electron
Device Letters and also in a talk this week at the American Physical Society
meeting by Tomás Palacios, assistant professor in MIT's Department of Electrical
Engineering and Computer Science and a core member of the Microsystems
Technology Laboratories. The work was done by Palacios along with EECS Assistant
Professor Jing Kong and two of their students, Han Wang and Daniel Nezich.
"In electronics, we're always trying to increase the frequency," Palacios
says, in order to make "faster and faster computers" and cellphones that can
send data at higher rates, for example. "It's very difficult to generate high
frequencies above 4 or 5 gigahertz," he says, but the new graphene technology
could lead to practical systems in the 500 to 1,000 gigahertz range.
"Researchers have been trying to find uses for this material since its
discovery in 2004," he says. "I believe this application will have tremendous
implications in high-frequency communications and electronics." By running
several of the frequency-doubling chips in series, it should be possible to
attain frequencies many times higher than are now feasible.
While the work is still at the laboratory stage, Palacios says, because it is
mostly based on relatively standard chip processing technology he thinks
developing it to a stage that could become a commercial product "may take a year
of work, maximum two." This project is currently being partially funded by the
MIT Institute for Soldier Nanotechnology and by the Interconnect Focus Center
program, and it has already attracted the interest of "many other offices in the
federal government and major chip-making companies," according to Palacios.
Graphene is related to the better-known buckyballs and carbon nanotubes,
which also are made of one-atom-thick sheets of carbon. But in those materials,
the carbon sheets are rolled up in the form of a tube or a ball. While
physicists had long speculated that flat sheets of the material should be
theoretically possible, some had doubted that it could ever remain stable in the
real world.
"In physics today, graphene is, arguably, the most exciting topic," Palacios
says. It is the strongest material ever discovered, and also has a number of
unsurpassed electrical properties, such as "mobility" -- the ease with which
electrons can start moving in the material, key to use in electronics -- which
is 100 times that of silicon, the standard material of computer chips.
One key factor in enabling widespread use of graphene will be perfecting
methods for making the material in sufficient quantity. The material was first
identified, and most of the early work was based on, using "sticky tape
technology," Palacios explains. That involves taking a block of graphite,
pressing a piece of sticky tape against it, peeling it off and then applying the
tape to a wafer of silicon or other material.
But Kong has been developing a method for growing entire wafers of graphene
directly, which could make the material practical for electronics. Kong and
Palacios' groups are currently working to transfer the frequency multipliers to
these new graphene wafers.
"Graphene will play a key role in future electronics," Palacios says. "We
just need to identify the right devices to take full advantage of its
outstanding properties. Frequency multipliers could be one of these devices."
About the researcher :
1. Tomás Palacios
Assistant Professor
Department of Electrical Engineering and Computer Science
Massachusetts Institute of Technology.
Assistant Professor of Electrical Engineering
Department of Electrical Engineering and Computer Science
Room 13-3065
77 Massachusetts Avenue
Cambridge, MA 02139
617.324.4068—Tel
617.324.5293—Fax
jingkong@mit.edu
| Tags: |
microchips - graphene - frequency multiplier - carbon nanotubes - |
| Research Documents: |
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