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Strength effects in diamond under shock compression from 0.1 to 1 TPa (PDF) Physical Review B
Diamonds are forever... solid and strong, Newsline, Mar. 6, 2009
Molecular building blocks made of diamonds, Science & Technology Review, Mar/Apr 2008
Livermore researchers shed new light on the physical properties of carbon, LLNL news release, Jan. 23, 2006
A laboratory to probe a planet's deep interior, Science & Technology Review, Jul/Aug 2007
| Contact: Anne M. Stark
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January 26, 2010
Diamond is one tough cookie
LIVERMORE, Calif. — Most people know that diamond is one of the hardest solids on Earth, so strong that it can easily cut through glass and steel.
Time-integrated photograph of an OMEGA laser shot (43633) to measure high-pressure diamond strength. The diamond target is at the center, surrounded by various diagnostics. The bright white light is ablated plasma, and radial yellow lines are tracks of hot target fragments very late in time.
Photo by Eugene Kowaluk/LLE
Click for high resolution image
Surprisingly, very little is known about the strength of diamond at extreme conditions. But new research by Lawrence Livermore National Laboratory scientists shows that diamond becomes even stronger during rapid compression.
Using the Janus laser at LLNL and the Omega laser at the University of Rochester, Livermore scientists and Rochester and UC Berkeley colleagues showed that when shock waves are applied to diamond with powerful lasers, it can support almost a million times atmospheric pressure before being crushed.
The research has implications for the technological uses of diamond.
“It could also provide insights into the ancient history of natural diamonds found on Earth and in meteorites, where shock waves caused by impact are common,” said Stewart McWilliams, lead author of a paper appearing in the upcoming edition of the journal, Physical Review B.
McWilliams conducted the experiments as a graduate student at UC Berkeley while on a Student Employee Graduate Research Fellowship (SEGRF) at LLNL.
Most natural diamonds are formed at high-pressure, high-temperature conditions existing at depths of 87 to 120 miles in the Earth’s mantle. Carbon-containing minerals provide the carbon source, and the growth occurs over periods from 1 billion to 3.3 billion years (25 percent to 75 percent of the age of the Earth).
In the recent research, the team measured the behavior of natural diamond crystals under shock-wave compression between 1 million and 10 million atmospheres of pressure, and the diamonds were crushed and melted in just a nanosecond (one billionth of a second).
“What we found is that diamond exhibits considerable strength right up to the point it melts,” McWilliams said.
“We reached some surprising conclusions about the strength of diamond,” said LLNL co-author Jon Eggert. “This type of research informs us about the interiors of the gas giants as well our own planet.”
Earlier research conducted by Livermore scientists show that diamond melts at around 6 million atmospheres of pressure and 14,000 degrees Fahrenheit. Their experiments mimicked conditions on the icy gas giant planets (Uranus and Neptune) where, according to their research, icebergs of diamond could float on a sea of liquid carbon.
Other Livermore authors include Damien Hicks, David Bradley, Peter Celliers, and Gilbert Collins.
Founded in 1952, Lawrence Livermore National Laboratory is a national security laboratory that develops science and engineering technology and provides innovative solutions to our nation's most important challenges. Lawrence Livermore National Laboratory is managed by Lawrence Livermore National Security, LLC for the U.S. Department of Energy's National Nuclear Security Administration.