On crystal surfaces, nanotubes self-guide themselves into dense structures with exciting potential applications as sensors or integrated circuits
USC researchers have found that sapphire surfaces spontaneously arrange carbon nanotubes into useful patterns - but only the right surfaces.
Nanotubes are one-atom thick sheets of carbon rolled into seamless cylinders. They can be used to work as chemical sensors and transistors, like devices made from carbon's close chemical cousin, silicon.
As a substrate for the creation of single wall nanotube (SWNT) devices, sapphire has a critical advantage, says Chongwu Zhou of the USC Viterbi School of Engineering's department of electrical engineering.
Single walled carbon nanotubes will grow along certain crystalline orientations on sapphire. No template has to be provided to guide this structuring: it takes place automatically.
Or more accurately, it sometimes happens automatically. With an elegant experiment, Zhou has resolved how and why this occurs.
The process is potentially predictable and controllable, opening the door for systematic exploration of sapphire as a SWNT (single wall nanotube) transistor medium.
In a paper accepted by the Journal of the American Chemical Society (V127, P5294, 2005), Zhou says the understanding "may allow registration-free fabrication and integration of nanotube devices by simply patterning source/ drain electrodes at desired locations, as the active material (i.e., nanotubes) is all over the substrate," to build such devices as sensors and integrated circuits for various uses.
According to Zhou, nanotube transistor devices now have to be painstakingly positioned and aligned using methods such as flow alignment and electrical-field-assisted alignment and then individually connected.
Zhou believes exploitation of the properties of sapphire his team investigated may allow production of the right kinds of dense, ordered arrays necessary.
Sapphire is aluminum oxide, also known as the mineral alumina, the abrasive corundum, and when colored by small quantities of iron, ruby. It is readily available as a cheap synthetic.
The crystal is six-sided, rising from a flat base, (see diagram, right) and has four natural planes on which it can be split to form thin, smooth slices: one parallel to the base, and three other vertical ones (see diagram). The self-guiding phenomenon was first reported last year by a research team at the Weizman Institute in Israel.
Zhou's team systematically investigated the phenomenon. Certain vertical slices, particularly the a- and r-planes, exhibit the self-guiding nanotube behavior. The c-plane, parallel to the base did not.
According to Zhou, two possibilities might explain the difference. One would be the arrangement of the atoms in the matrix; the other, differences in the "step edge" properties of the surfaces.
Step edges are nanoscopic surface irregularities, minute rises from the suface level.
To eliminate step edges as a possibility, Zhou's group annealed (treated with high, long-lasting heat) samples of both forms, and then tested. Annealing emphasizes step edges, and would accordingly emphasize the arrangement effect, if the effect was dependent on the edges. It did not.
The basal, horizontal slices remained unable to self-guide nanotubes. The two of the vertical slices continued to do so. The behavior seems to be due to the varied arrangement of aluminum and oxygen atoms on the surface.
Zhou's team is now investigating how the exact mechanisms at work, in order to further control the process.
Zhou and his team have also, worked with quartz substrates for nanotube synthesis, which did not exhibit any guided growth.
Zhou worked with Xiaolei Liu and Song Han on the research, which was supported by an NSF career Award, an NSF-CENS grant, and an SRC MARCO/ DARPA grant.
USC Viterbi School of Engineering
Subscribe To SpaceDaily Express
NASA Awards $11 Million "Quantum Wire" Contract To Rice
Houston TX (SPX) Apr 25, 2005
NASA has awarded Rice University's Carbon Nanotechnology Laboratory a four-year, $11 million contract to produce a prototype power cable made entirely of carbon nanotubes.
|The content herein, unless otherwise known to be public domain, are Copyright 1995-2016 - Space Media Network. All websites are published in Australia and are solely subject to Australian law and governed by Fair Use principals for news reporting and research purposes. AFP, UPI and IANS news wire stories are copyright Agence France-Presse, United Press International and Indo-Asia News Service. ESA news reports are copyright European Space Agency. All NASA sourced material is public domain. Additional copyrights may apply in whole or part to other bona fide parties. Advertising does not imply endorsement, agreement or approval of any opinions, statements or information provided by Space Media Network on any Web page published or hosted by Space Media Network. Privacy Statement All images and articles appearing on Space Media Network have been edited or digitally altered in some way. Any requests to remove copyright material will be acted upon in a timely and appropriate manner. Any attempt to extort money from Space Media Network will be ignored and reported to Australian Law Enforcement Agencies as a potential case of financial fraud involving the use of a telephonic carriage device or postal service.|