Graphene is often touted as a miracle material — it easily conducts electricity and it's hundreds of times stronger than steel. But now tests of real-world samples of graphene show that while the carbon material is possibly the strongest material produced today, it's also as brittle as ordinary ceramic.
Result? It can crack.
A team of scientists from Rice University and the Georgia Institute of Technology tested small pieces of "bilayer" graphene, two single-atom-thick sheets of pure carbon resting one atop the other,by making tiny cracks in them with focused beams of ions. They then pulled and twisted the graphene, to see how fast the cracks expanded until the material broke. [8 Chemical Elements You've Never Heard Of]
"It's very sensitive to [the] presence of [a] crack. In steel if you have a crack, there, it's not so dangerous. Steel has a huge resistance to crack extension. Graphene is more like window glass," said Ting Zhu, an associate professor of mechanical engineering at Georgia Tech and one of the authors of the study.
The measure of a material's resistance to cracks, called fracture toughness, is not just the tensile strength — how likely it is to break when tugged on. It also measures how much punishment a given substance can take before cracking when being twisted. Metals, for instance, are ductile; it takes a lot of twisting and bending to break a spoon. A piece of glass resists twisting and doesn't stretch, but it breaks quickly if any twisting or pulling force is applied past a certain threshold, and even a tiny crack will make it shatter.
Zhu, working with Jun Lou at Rice, found that graphene with cracks is 10 times more prone to breakage than steel, and closer in fracture toughness to aluminum oxide or silicon carbide-based ceramics.
The relatively low fracture toughness means that it takes only a small crack in a piece of graphene to weaken it. And such small cracks are a natural consequence of making graphene.
Graphene is made in several ways, among them chemical vapor deposition, in which carbon vapor is allowed to cool and settle on a surface, and exfoliation, in which graphite (from which graphene is derived) is put into a solvent. The sheets of graphene can be large in the former case, but they aren't perfect. The resulting lattice of carbon atoms that makes up the graphene has small defects — an atom missing or misaligned here and there. The defects won't make much difference when using graphene as a conductor or semiconductor, but for mechanical applications, such as making flexible displays or boosting structural strength of other materials, the imperfections start to matter.
Perfect graphene can take about 100 Gigapascals (14 million pounds per square inch) of force before it breaks. But the imperfect graphene the researchers made can withstand only a tiny fraction of that, about 4 Megapascals (580 pounds per square inch).
The experiments aren't just important for the study of graphene. Other materials that can take on a two-dimensional structure might behave in a similar way, and as such the new research, detailed on April 29 in the journal Nature Communications, might offer important insights.
"This kind of modeling could be applied to study many other 2-D materials, such as aluminum disulfide or boron nitride," Ting said.
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