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IBM Builds IC Around Nanotube Molecule

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YORKTOWN HEIGHTS, N.Y., March 28, 2006 -- IBM announced this week that its researchers have built the first complete electronic integrated circuit (IC) around a single carbon nanotube molecule, a new material that shows promise for providing enhanced performance over today’s standard silicon semiconductors.

IBM said the achievement is significant because the circuit was built using standard semiconductor processes and used a single molecule as the base for all components in the circuit, rather than linking together individually constructed components. This can simplify manufacturing and provide the consistency needed to more thoroughly test and adjust the material for use in these applications, the company said in a statement.

Size comparison between IBM's single nanotube ring oscillator circuit and a human's hair. (IBM Research)
"Carbon nanotube transistors have the potential to outperform state-of-the-art silicon devices," said T.C. Chen, vice president, Science & Technology, IBM Research. "However, scientists have focused so far on fabricating and optimizing individual carbon nanotube transistors. Now, we can evaluate the potential of carbon nanotube electronics in complete circuits -- a critical step toward the integration of the technology with existing chip-making techniques."

For some 50 years, the semiconductor industry has relied on the ability to pack increasing numbers of electronic circuits on a single silicon chip to make those chips more powerful. This was achieved largely by finding ways to build smaller circuits. With scientists seeing an end to that capability looming, the use of nanotechnology is being explored as a means to keep the industry moving forward, IBM said.

The field of nanotechnology involves the synthesis and assembly of new types of molecules and structures with dimensions measured in billionths of a meter. Looking like "a microscopic roll of chicken wire," carbon nanotubes measure 50,000 times thinner than a human hair, IBM said. "Yet they have unique properties that may allow them to carry higher current densities than the 'pipes' currently used in today’s transistor and, with their smaller size, might allow for further miniaturization."

A close-up view of the five-stage CMOS-type nanotube ring oscillator. The upper right inset shows the nanotube itself with a diameter of ~2 nm. (IBM Research)
The circuit built by the IBM team was a ring oscillator -- a circuit chip makers typically build to evaluate new manufacturing processes or materials. The circuit stresses certain properties that can give a good indication of how new technologies will perform when used to build complete chips, the researchers said.

By integrating the complete circuit around a single nanotube, the IBM team said, it observed circuit speeds nearly a million times faster than previously demonstrated circuits with multiple nanotubes. While this is still slower than the speeds obtained by today’s silicon chips, the IBM said new nanofabrication processes will eventually unlock the superior performance potential of carbon nanotube electronics.

The scientists said they will now use the ring oscillator to test improved carbon nanotube transistors and circuits, and to gauge their performance in complete chip designs.

"An Integrated Logic Circuit Assembled on a Single Carbon Nanotube," by Zhihong Chen, Joerg Appenzeller, Yu-Ming Lin, Paul Solomon and Phaedon Avouris of IBM’s T. J. Watson Research Center, Yorktown Heights, NY; Jennifer Sippel-Oakley and Andrew G. Rinzler of the Department of Physics, University of Florida, Gainesville; and Jinyao Tang and Shalom J. Wind of the Department of Chemistry and the Department of Applied Physics and Applied Mathematics, Columbia University; is published in this week's Science journal.

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Mar 2006
That branch of science involved in the study and utilization of the motion, emissions and behaviors of currents of electrical energy flowing through gases, vacuums, semiconductors and conductors, not to be confused with electrics, which deals primarily with the conduction of large currents of electricity through metals.
Basic Sciencecarbon nanotubeelectronic integrated circuitelectronicsIBMICindustrialnanotubeNews & Featuressilicon devicessilicon semiconductors

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