Buckypaper is 10 times lighter but potentially 500 times stronger than steel when sheets of it are stacked and pressed together to form a composite. Unlike conventional composite materials, though, it conducts electricity like copper or silicon and disperses heat like steel or brass.
Buckypaper is made from tube-shaped carbon molecules, 50,000 times thinner than a human hair, that were first developed in the early 1990s. Buckypaper owes its name to Buckminsterfullerene, or Carbon 60 - a type of carbon molecule whose powerful atomic bonds make it twice as hard as a diamond.
Buckypaper is made from tube-shaped carbon molecules, 50,000 times thinner than a human hair, that were first developed in the early 1990s. Buckypaper owes its name to Buckminsterfullerene, or Carbon 60 - a type of carbon molecule whose powerful atomic bonds make it twice as hard as a diamond.
Among the possible uses for buckypaper that are being researched at FAC2T:
- If exposed to an electric charge, buckypaper could be used to illuminate computer and television screens. It would be more energy-efficient, lighter, and would allow for a more uniform level of brightness than current cathode ray tube (CRT) and liquid crystal display (LCD) technology.
- As one of the most thermally conductive materials known, buckypaper lends itself to the development of heat sinks that would allow computers and other electronic equipment to disperse heat more efficiently than is currently possible. This, in turn, could lead to even greater advances in electronic miniaturization.
- Because it has an unusually high current-carrying capacity, a film made from buckypaper could be applied to the exteriors of airplanes. Lightning strikes then would flow around the plane and dissipate without causing damage.
- Films also could protect electronic circuits and devices within airplanes from electromagnetic interference, which can damage equipment and alter settings. Similarly, such films could allow military aircraft to shield their electromagnetic "signatures," which can be detected via radar.
So far, buckypaper can be made at only a fraction of its potential strength, in small quantities and at a high price.
Carbon nanotubes are already beginning to be used to strengthen tennis rackets and bicycles, but in small amounts. The epoxy resins used in those applications are 1 to 5 percent carbon nanotubes, which are added in the form of a fine powder. Buckypaper, which is a thin film rather than a powder, has a much higher nanotube content - about 50 percent
Carbon nanotubes are already beginning to be used to strengthen tennis rackets and bicycles, but in small amounts. The epoxy resins used in those applications are 1 to 5 percent carbon nanotubes, which are added in the form of a fine powder. Buckypaper, which is a thin film rather than a powder, has a much higher nanotube content - about 50 percent
No comments:
Post a Comment