Nanotubes conduct electricity, but since they’re so small, it’s not easy to attach wires to make electrical measurements. The image shows four electrical contacts deposited over a long nanotube, and the resulting measurements showed that some nanotubes conduct like metals and others like silicon, the material of transistors. In fact, the idea of building transistors and eventually computers out of nanotubes has created a lot of excitement.

Tungsten leads (bright yellow) deposited to make electrical contact with a nanotube; the contacts are about 80 microns wide; resulting measurements showed some nanotubes are conductors, like copper wire, and others are semiconductors, like silicon, the material of transistors (photo courtesy of Henri Lezec, ISIS, Université Louis Pasteur, Strasbourg France)

A nanotube filled with buckyballs. The wavy pattern shows the electron density inside the nanotube. (photo courtesy of Ali Yazdani, University of Illinois)

Nanotubes in an electric field spray out electrons. In this experiment, these electrons strike the phosphor coating inside an evacuated glass tube and make it glow, illuminating physicist Olivier Noury. (photo courtesy of Jean-Marc Bonard, École Polytechnique Fédérale de Lausanne)

Finding a way to control nanotube conductivity has been the focus of much research. One promising approach is to fill the nanotubes with buckyballs—one new form of carbon encapsulated in another to create what is picturesquely termed a “nanoscopic peapod”. (See image.) The number and location of the buckyballs determine the electronic properties of the peapod, an important step on the road to an active electronic device.

Nanotube transistors have in fact been constructed, but they cannot yet be fabricated and connected together in large numbers, nothing like the 50 million transistors on a modern computer processor chip. Nevertheless, nanotubes are leading candidates to replace silicon in the drive to further miniaturize the transistor.

In a different kind of electrical application, when a voltage is applied to a bundle of nanotubes in a vacuum, the nanotubes produce a spray of electrons. If these nanotubes are placed inside a phosphor-coated glass tube and a voltage is applied, the nanotubes give off electrons, which strike the phosphor and make it glow, much like a fluorescent light. The photo shows one of these nanotube lamps. This effect may also lead to a new flat-screen color display for video.

Developing some of these applications can require exacting work with individual nanotubes. When they form in soot, they are part of a tangled mass, as shown in the image on the left. But now nanotubes can be produced in neat arrays, as shown in the image on the right, which could facilitate construction of a device from individual nanotubes. Stay tuned for more news on nano-applications!

Mat of nanotubes in the soot from a carbon arc discharge (image courtesy Rensselaer Polytechnic Institute)

Nanotubes grown in an array (image courtesy of NASA)