Nanodiamonds, bits of crystalline carbon hundreds of thousands of times smaller than a grain of sand, have intriguing surface and chemical properties with potential applications in medicine, optoelectronics and quantum computing. To forge these nanoscopic gemstones, researchers expose organic explosive molecules to powerful detonations in a controlled environment. These explosive forces, however, make it difficult to study the nanodiamond formation process, even under laboratory conditions.

To overcome this hurdle, a pair of French researchers recently developed a procedure and a computer model that can simulate the highly variable conditions of explosions on phenomenally short time scales. The team reports their work in The Journal of Chemical Physics, from AIP Publishing.

"Understanding the processes that form nanodiamonds is essential to control or even tune their properties, making them much better suited for specific purposes," said Xavier Bidault, a researcher at CEA DAM Ile-de-France, and a co-author on the paper.

Bidault and his co-author Nicolas Pineau used a type of simulation known as Reactive Molecular Dynamics, which simulates the time evolution of complex, chemically reactive systems down to the atomic level.

"The atomic-level interaction model is essential to really understand what's happening," said Pineau. "It gives us an intimate way to analyze, step-by-step, how carbon-rich compounds can form nanodiamonds in a high-pressure, high-temperature system."

Due to the extreme and fleetingly brief conditions of a detonation, actual experimental investigation is impractical, so researchers must rely on atomic-level simulations that show how and where this chemistry occurs.

The new results reveal that a delicate balance of temperature and pressure evolution is necessary for nanodiamonds to form at all. If the initial detonation pressure is too low, carbon solids are able to form, but not diamonds. If the pressure is too high, the carbon "seeds" of nanodiamonds become polluted by other elements, such as oxygen or nitrogen, which prevent the transition to diamond.

Scientists have known for more than 50 years that nanodiamonds form from detonations, but the atomic-level details of their formation have been an open question for at least the last two decades. The most common industrial route for their synthesis is the detonation of carbon-rich organic high explosives. Nanodiamonds can also form naturally from explosive volcanic eruptions or asteroid impacts on Earth.

"Our work shows that the right path seems to be a high initial pressure followed by a sharp pressure decrease," said Bidault. If the precise conditions are met, nanodiamonds form. These complex pressure paths are typical of detonation processes.

Research Report: "Dynamic formation of nanodiamond precursors from the decomposition of carbon suboxide (C3O2) under extreme conditions-A ReaxFF study,"

Related Links
American Institute of Physics
Carbon Worlds - where graphite, diamond, amorphous, fullerenes meet

Tweet

Thanks for being there; We need your help. The SpaceDaily news network continues to grow but revenues have never been harder to maintain. With the rise of Ad Blockers, and Facebook - our traditional revenue sources via quality network advertising continues to decline. And unlike so many other news sites, we don't have a paywall - with those annoying usernames and passwords. Our news coverage takes time and effort to publish 365 days a year. If you find our news sites informative and useful then please consider becoming a regular supporter or for now make a one off contribution.
SpaceDaily Monthly Supporter $5+ Billed Monthly Option 1 : $5.00 USD - monthly Option 2 : $10.00 USD - monthly Option 3 : $15.00 USD - monthly Option 4 : $20.00 USD - monthly Option 5 : $25.00 USD - monthly Option 6 : $50.00 USD - monthly Option 7 : $100.00 USD - monthly paypal only		SpaceDaily Contributor $5 Billed Once credit card or paypal

Self-healing material can build itself from carbon in the air
Boston MA (SPX) Oct 12, 2018
A material designed by MIT chemical engineers can react with carbon dioxide from the air, to grow, strengthen, and even repair itself. The polymer, which might someday be used as construction or repair material or for protective coatings, continuously converts the greenhouse gas into a carbon-based material that reinforces itself. The current version of the new material is a synthetic gel-like substance that performs a chemical process similar to the way plants incorporate carbon dioxide from the ... read more