Perfect sheets of diamond a few atoms thick appear to be possible even without the big squeeze that makes natural gems.
Scientists have speculated about it and a few laboratories have even seen signs of what they call diamane, an extremely thin film of diamond that has all of diamond’s superior semiconducting and thermal properties.
Now researchers at Rice Univ. and in Russia have calculated a “phase diagram” for the creation of diamane. The diagram is a road map. It lays out the conditions—temperature, pressure and other factors—that would be necessary to turn stacked sheets of graphene into a flawless diamond lattice.
In the process, the researchers determined diamane could be made completely chemically, with no pressure at all, under some circumstances.
The team led by Rice theoretical physicist Boris Yakobson and Pavel Sorokin, a former postdoctoral associate at Rice and now a senior researcher at the Technological Institute for Superhard and Novel Carbon Materials in Moscow, reported results in Nano Letters.
“Diamanes have a wide potential range of application,” Sorokin said. “They can be applied as very thin, dielectric hard films in nanocapacitors or mechanically stiff, nanothick elements in nanoelectronics. Also, diamanes have potential for application in nano-optics.
“The possibility of obtaining such a quasi-two-dimensional object is intriguing, but available experimental data prevents the expectation of its fabrication using traditional methods. However, the ‘bottom-up’ approach proposed by Richard Feynman allows the fabrication of diamanes from smaller objects, such as graphene.”
The researchers built computer models to simulate the forces applied by every atom involved in the process. That includes the graphene, as well as the hydrogen (or, alternately, a halogen) that promotes the reaction.
Conditions, they learned, need to be just right for a short stack of graphene pancakes to collapse into a diamond matrix—or vice versa—via chemistry.
“A phase diagram shows you which phase dominates the ground state for each pressure and temperature,” Yakobson said. “In the case of diamane, the diagram is unusual because the result also depends on thickness, the number of layers of graphene. So we have a new parameter.”
Hydrogen isn’t the only possible catalyst, he said, but it’s the one they used in their calculations. “When the hydrogen attacks, it takes one electron from a carbon atom in graphene. As a result, a bond is broken and another electron is left hanging on the other side of the graphene layer. It’s now free to connect to a carbon atom on the adjacent sheet with little or no pressure.
“If you have several layers, you get a domino effect, where hydrogen starts a reaction on top and it propagates through the bonded carbon system,” he said. “Once it zips all the way through, the phase transition is complete and the crystal structure is that of diamond.”
Yakobson said the paper doesn’t cover a possible deal-breaker. “The conversion from one phase to another starts from a small seed, a nucleation site, and in this process there’s always what is called a nucleation barrier. We don’t calculate that here.” He said carbon normally prefers to be graphite (the bulk form of carbon used as pencil lead) rather than diamond, but a high nucleation barrier prevents diamond from making the transition.
“Thermodynamically, an existing diamond should become graphite, but it doesn’t happen for exactly this reason,” Yakobson said. “So sometimes it’s a good thing. But if we want to make flat diamond, we need to find ways to circumvent this barrier.”
He said the manufacture of synthetic diamond, which was first reliably made in the 1950s, requires very high pressures of about 725,000 pounds per square inch. Manufactured diamonds are used in hardened tools for cutting, as abrasives and even as high-quality gemstones grown via techniques that simulate the temperatures and pressures found deep in Earth, where natural diamond is forged.
Diamond films are also routinely made via chemical vapor deposition, “but they’re always very poor quality because they’re polycrystalline,” Yakobson said. “For mechanical purposes, like very expensive sandpaper, they’re perfect. But for electronics, you would need high quality for it to serve as a wide-band gap semiconductor.”
Source: Rice Univ.