Nanodiamonds Could Help Spacecraft Withstand Meteorite Impacts

Researchers use high-velocity impacts to make new nanomaterials.

Experiments at Rice University showed nanodiamonds and other forms of carbon were created when carbon nanotube pellets were fired at a target at hypervelocity. (Image courtesy of Pedro Alves da Silva Autreto.)

Experiments at Rice University showed nanodiamonds and other forms of carbon were created when carbon nanotube pellets were fired at a target at hypervelocity. (Image courtesy of Pedro Alves da Silva Autreto.)

Superman can famously make a diamond by crushing a chunk of coal in his hand, but researchers at Rice University are employing a different tactic.

Rice materials scientists are making nanodiamonds and other forms of carbon by smashing nanotubes against a target at high speeds. Nanodiamonds won’t make anyone rich, but the process of making them will enrich the knowledge of engineers who design structures that resist damage from high-speed impacts.

The diamonds are the result of a detailed study on the ballistic fracturing of carbon nanotubes at different velocities. The results showed that such high-energy impacts caused atomic bonds in the nanotubes to break and sometimes recombine into different structures.

The work led by the labs of materials scientists Pulickel Ajayan at Rice and Douglas Galvao at the State University of Campinas, Brazil, is intended to help aerospace engineers design ultralight materials for spacecraft and satellites that can withstand impacts from high-velocity projectiles like micrometeorites.

The research appears in the American Chemical Society journal ACS Applied Materials and Interfaces.

Simulation showing the interaction between two nanotubes shot at a target at hypervelocity. Remnants of the nanotubes form diamon-like amorphous carbon and grain boundaries. (Video courtesy of Galvao Group/State University of Campinas.)

Knowing how the atomic bonds of nanotubes can be recombined will give scientists and engineers clues to develop lightweight materials by rearranging those bonds, said co-lead author and Rice graduate student Sehmus Ozden.

“Satellites and spacecraft are at risk of various destructive projectiles, such as micrometeorites and orbital debris,” Ozden said. “To avoid this kind of destructive damage, we need lightweight, flexible materials with extraordinary mechanical properties. Carbon nanotubes can offer a real solution.”

The researchers packed multiwalled carbon nanotubes into spherical pellets and fired them at an aluminum target in a two-stage light-gas gun at Rice, and then analyzed the results from impacts at three different speeds.

At what the researchers considered a low velocity of 3.9 kilometers per second, a large number of nanotubes were found to remain intact. Some even survived higher velocity impacts of 5.2 kilometers per second. But very few were found among samples smashed at a hypervelocity of 6.9 kilometers per second. The researchers found that many, if not all, of the nanotubes split into nanoribbons, confirming earlier experiments.

Co-author Chandra Sekhar Tiwary, a Rice postdoctoral researcher, noted the few nanotubes and nanoribbons that survived the impact were often welded together, as observed in transmission electron microscope images.

Transmission electron microscope images show nanodiamonds in samples of nanotubes fired at a target at high velocity. The insert shows the diffraction pattern identifying the formations as nanodiamonds. (Image courtesy of Ajayan Group/Rice University.)

Transmission electron microscope images show nanodiamonds in samples of nanotubes fired at a target at high velocity. The insert shows the diffraction pattern identifying the formations as nanodiamonds. (Image courtesy of Ajayan Group/Rice University.)

“In our previous report, we showed that carbon nanotubes form graphene nanoribbons at hypervelocity impact,” Tiwary said. “We were expecting to get welded carbon nanostructures, but we were surprised to observe nanodiamond as well.” The orientation of nanotubes both to each other and in relation to the target and the number of tube walls were as important to the final structures as the velocity, Ajayan said.

“The current work opens a new way to make nanosize materials using high-velocity impact,” said co-lead author Leonardo Machado of the Brazil team.

For more nanotechnology news, find out how a microwave oven treatment yields high-quality graphene.