The brittle material can turn flexible when made into ultrafine needles,
researchers find.
By David L. Chandler, MIT News Office
By David L. Chandler, MIT News Office
April 19, 2018 -- Diamond is
well-known as the strongest of all natural materials, and with that strength
comes another tightly linked property: brittleness. But now, an international
team of researchers from MIT, Hong Kong , Singapore , and Korea
The
surprising finding is being reported this week in the journal Science, in a paper by senior
author Ming Dao, a principal research scientist in MIT’s Department of
Materials Science and Engineering; MIT postdoc Daniel Bernoulli; senior author
Subra Suresh, former MIT dean of engineering and now president of Singapore’s
Nanyang Technological University; graduate students Amit Banerjee and Hongti
Zhang at City University of Hong Kong; and seven others from CUHK and
institutions in Ulsan, South Korea.
The
results, the researchers say, could open the door to a variety of diamond-based
devices for applications such as sensing, data storage, actuation,
biocompatible in vivo imaging, optoelectronics, and drug delivery. For example,
diamond has been explored as a possible biocompatible carrier for delivering
drugs into cancer cells.
The
team showed that the narrow diamond needles, similar in shape to the rubber
tips on the end of some toothbrushes but just a few hundred nanometers
(billionths of a meter) across, could flex and stretch by as much as 9 percent
without breaking, then return to their original configuration, Dao says.
Ordinary
diamond in bulk form, Bernoulli says, has a limit of well below 1 percent
stretch. “It was very surprising to see the amount of elastic deformation the
nanoscale diamond could sustain,” he says.
“We
developed a unique nanomechanical approach to precisely control and quantify
the ultralarge elastic strain distributed in the nanodiamond samples,” says
Yang Lu, senior co-author and associate professor of mechanical and biomedical
engineering at CUHK. Putting crystalline materials such as diamond under
ultralarge elastic strains, as happens when these pieces flex, can change their
mechanical properties as well as thermal, optical, magnetic, electrical,
electronic, and chemical reaction properties in significant ways, and could be
used to design materials for specific applications through “elastic strain
engineering,” the team says.
The
team measured the bending of the diamond needles, which were grown through a
chemical vapor deposition process and then etched to their final shape, by
observing them in a scanning electron microscope while pressing down on the
needles with a standard nanoindenter diamond tip (essentially the corner of a
cube). Following the experimental tests using this system, the team did many
detailed simulations to interpret the results and was able to determine
precisely how much stress and strain the diamond needles could accommodate
without breaking.
The
researchers also developed a computer model of the nonlinear elastic
deformation for the actual geometry of the diamond needle, and found that the
maximum tensile strain of the nanoscale diamond was as high as 9 percent. The
computer model also predicted that the corresponding maximum local stress was
close to the known ideal tensile strength of diamond — i.e. the theoretical
limit achievable by defect-free diamond.
When
the entire diamond needle was made of one crystal, failure occurred at a
tensile strain as high as 9 percent. Until this critical level was reached, the
deformation could be completely reversed if the probe was retracted from the
needle and the specimen was unloaded. If the tiny needle was made of many grains
of diamond, the team showed that they could still achieve unusually large
strains. However, the maximum strain achieved by the polycrystalline diamond
needle was less than one-half that of the single crystalline diamond
needle.
Yonggang
Huang, a professor of civil and environmental engineering and mechanical
engineering at Northwestern
University
Huang
adds “When elastic strains exceed 1 percent, significant material property
changes are expected through quantum mechanical calculations. With controlled
elastic strains between 0 to 9 percent in diamond, we expect to see some
surprising property changes.”
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