Measuring performance of carbon nanotubes as building blocks for ultra-tiny computer chips of the future
There is this really great story from IBM Research Labs that I simply have to seed here for my readers.
IBM’s scientists have created a method to measure the performance of carbon nanotubes as building blocks for ultra-tiny computer chips of the future. Of course, you can also read it on IBM Research Lab’s site as well as on CIOL’s semicon site.
IBM scientists have measured the distribution of electrical charges in tubes of carbon that measure less than 2nm in diameter, 50,000 times thinner than a strand of human hair.
This novel technique, which relies on the interactions between electrons and phonons, provides a detailed understanding of the electrical behavior of carbon nanotubes, a material that shows promise as a building block for much smaller, faster and lower power computer chips compared to today’s conventional silicon transistors.
Phonons are the atomic vibrations that occur inside material, and can determine the material’s thermal and electrical conductivity. Electrons carry and produce the current. Both are important features of materials that can be used to carry electrical signals and perform computations.
The interaction between electrons and phonons can release heat and impede electrical flow inside computer chips. By understanding the interaction of electrons and phonons in carbon nanotubes, the researchers have developed a better way to measure their suitability as wires and semiconductors inside of future computer chips.
In order to make carbon nanotubes useful in building logic circuitry, scientists are pushing to demonstrate their high speed, high packing density and low power consumption capabilities as well as the ability to make them viable for potential mass production.
Dr. Phaedon Avouris, IBM Fellow and lead researcher for IBM’s carbon nanotube efforts, said: “The success of nanoelectronics will largely depend on the ability to prepare well characterized and reproducible nano-structures, such as carbon nanotubes. Using this technique, we are now able to see and understand the local electronic behavior of individual carbon nanotubes.”
To date, researchers have been able to build carbon nanotube transistors with superior performance, but have been challenged with reproducibility issues. Carbon nanotubes are sensitive to environmental influences.
For example, their properties can be altered by foreign substances, affecting the flow of electrical current and changing device performance. These interactions are typically local and change the density of electrons in the various devices of an integrated circuit, and even along a single nanotube.