Date:      Mon Aug 27 14:59:24 2001

August 27, 2001
New York Times

I.B.M. Creates a Tiny Circuit Out of Carbon

By KENNETH CHANG

n another step toward post-silicon computers, I.B.M. (news/quote) scientists 
have built a computer circuit out of a single strand of carbon.

The I.B.M. circuit performs only a single, simple operation  flipping a 
"true" to "false" and vice versa  but it marks the first time that a device 
made of carbon strands known as nanotubes has been able to carry out any sort 
of logic. It is also the first logic circuit made of a single molecule.

At least another year or two of research is needed before I.B.M. can even 
evaluate whether a practical computer chip can be manufactured from 
nanotubes, said Dr. Phaedon Avouris, manager of nanoscale science at IBM 
Research and the lead scientist on the project.

But the fact that the researchers were able to build the circuit raises hopes 
that nanotubes could eventually be used for computer processors that pack up 
to 10,000 times more transistors in the same amount of space.

Dr. Avouris declined to speculate when a chip with nanotube circuitry might 
appear commercially, but he described nanotubes as "the best candidate from 
what we've seen" in the emerging field of molecular electronics.

"This is yet another test that nanotubes have passed," Dr. Avouris said. "The 
physics works."

The processing power of computer chips has consistently doubled every year or 
two as the size of transistors continues to shrink. But current chip-making 
technology, which etches circuits into silicon, is expected to run up against 
fundamental physics limits in 10 to 15 years.


 
A nanotube, which resembles a rolled-up tube of chicken wire, is about one 
hundred- thousandth the thickness of a human hair. Its thinness, only about 
10 atoms wide, makes it a promising candidate for circuits in future faster 
and smaller computer chips. It takes its name from nanometer, a unit of 
measurement one-billionth of a meter long, which is a convenient length for 
specifying molecular dimensions.

Dr. Charles M. Lieber, a professor of chemistry at Harvard and an expert in 
the field of nanotechnology, called the I.B.M. achievement "quite 
significant." The effort to incorporate nanotubes in computer chips is a 
"great strategy and one that could be implemented relatively quickly," he 
said.

The I.B.M. researchers presented their findings yesterday at a meeting of the 
American Chemical Society in Chicago. An article describing the results will 
appear in the September issue of the journal Nano Letters.

Nanotubes are not the only approach to building ultratiny circuits. Other 
researchers, like those at Hewlett-Packard (news/quote), have designed custom 
molecules that act as on- off switches. However, unlike transistors, the 
switches do not amplify electric signals, and a computer made of molecular 
switches would have to employ a different method for performing calculations, 
one that scientists are still working to devise.

"They don't even have a transistor," Dr. Avouris said. "In that sense, we're 
way ahead in the game. You don't have to worry about finding a different 
architecture. You use what exists now."

In April, the same researchers at I.B.M.'s T. J. Watson Research Center in 
Yorktown Heights, N.Y., reported that they had constructed vast arrays of 
transistors made out of carbon nanotubes, but the arrays were not wired up to 
perform any calculations.

In the latest research, the scientists succeeded in hooking up two of these 
transistors to perform the true-false flipping operation. Even more 
remarkably, the two transistors exist along sections of the same nanotube.

This function  a "not" operator  is one of three fundamental logic operations 
that underlie all computer calculations. (The other two operations are "and" 
and "or"; the "and" operator compares whether two statements are both true; 
the "or" operator determines if at least one statement is true.)

In the binary language of 1's and 0's used by computers, a "not" operator 
converts a "0" (the equivalent of "false") into a "1" ("true"). It also works 
the other way, changing a "1" into a "0." Computer calculations are all 
reduced to combinations of "and," "or" and "not" operators.

To build the circuit, the researchers draped a single nanotube on a silicon 
wafer over three parallel gold electrodes, added a layer of polymer between 
two of the electrodes and then sprinkled some potassium atoms on top.

All of the carbon nanotube transistors built previously were positive-type 
transistors, meaning that they carried current via empty spaces, or "holes," 
in the sea of electrons that act like positive charges. The sprinkled 
potassium atoms added enough electrons to the nanotube that its behavior 
changed to that of a negative-type transistor, where current is carried by 
electrons.

The piece of nanotube sprinkled with potassium atoms acted like a 
negative-type transistor; the section protected under the polymer layer 
remained a positive-type transistor. The combination of the two transistors 
formed a "not" operator, flipping an incoming voltage signal to an opposite 
output signal.

The ability to change positive-type transistors to negative-type is "a very 
neat trick" said Dr. Uzi Landman, a professor of physics at the Georgia 
Institute of Technology. "As a demonstration, it is an important step."

The logic circuit is about one-15,000th an inch wide  larger than the 
equivalent silicon structure  but Dr. Avouris said that it could eventually 
be shrunk so that 10,000 nanotube transistors fit in the space taken up by 
one current-day silicon transistor. "In principle, it can be small," he said. 
"It's a matter of just making the connections."

The I.B.M. researchers are now trying to build the more complicated "and" and 
"or" operators and tie them together into more complex circuits.