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Liquid Benzene Squeezed to Form Diamond Nanothreads

High-pressure cycles unexpectedly convert benzene into superstrong and ultrathin threads. Will they put a space elevator within reach?


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The classic Beatles song “Lucy in the Sky with Diamonds” may have a new meaning. Scientists announced they have likely discovered the strongest, stiffest diamond-based nanomaterial to date. Its properties suggest it could have important industrial applications, such as in transportation or aerospace manufacturing, and it might revive the idea of building elevators to space.   A team led by chemist John Badding of Pennsylvania State University took an approach reminiscent of the way Superman squeezed coal into diamond in comic books. The researchers found that isolated, liquid-state benzene molecules, which consist of rings of carbon atoms, assemble into surprisingly neat and orderly chains after enduring slow, alternating cycles of pressure. The resulting thread, merely three atoms across and thousands of times thinner than a strand of hair, appears to have a zigzagging arrangement of rings of carbon atoms in the shape of a triangular pyramid—a formation similar to diamond’s. Such a structure, which scientists didn’t know was possible until now, could be the strongest and most durable nanomaterial ever made.   Badding says that the team’s discovery was serendipitous: “Honestly, it was just an accident.” Thomas Fitzgibbons, a graduate student in Badding’s lab, wanted to study materials made by the organic chemical compound benzene. When isolated, benzene molecules can react in interesting ways to form unique structures. To study these structures using conventional techniques, however, Fitzgibbons needed large quantities of the product. He brought a sample of liquid benzene to a machine called a Paris-Edinburgh device at Oak Ridge National Laboratory in Tennessee and put the molecules into a high-pressure cell. In general, when a liquid is squeezed under intense pressure, it transforms into a solid. “It essentially freezes,” Badding says. Once frozen, benzene molecules align into predictable patterns of stacked columns.   What happened next is the unusual part. Scientists have generally believed that as compression continues, the benzene molecules eventually yield a sloppy, white powder. “People thought they’d react in a disorganized way and make a mess,” Badding says.   But instead of disarray, Fitzgibbons saw order. “That was a shock to us, to say the least,” Badding confesses. The researchers were so surprised, they deployed a battery of techniques to confirm the finding, including x-ray and neutron diffraction, transmission electron microscopy and vibrational spectroscopy. Their results were consistent: they saw order.   The reason for this unexpected alignment of benzene molecules may lie in the timing of the compression. Scientists generally create benzene materials in small amounts by quick cycles of pressure changes. To make more product, the compression cycles must be slower. “It seems we gave benzene molecules time to arrange into a pattern, particularly nanothreads,” Badding says. This slow compression was key to their discovery.   Yury Gogotsi, director of the A. J. Drexel Nanomaterials Institute at Drexel University, says that although the results are indeed exciting, he would like further confirmation and analysis of the material, for example using “much higher-resolution images, which can further shed light on the material’s structure,” Gogotsi says. “Assuming their interpretation is correct, which there’s good reason to believe, I think this discovery is significant.”   Before the nanothreads can be used commercially, Badding wants to determine their properties and behavior in different conditions and to understand exactly how the benzene molecules link up. The studies could take years, he says. Then engineers will need to figure out how best to mass-manufacture them and incorporate them into existing industrial infrastructure for various uses. For a start, these threads seem poised to replace carbon fiber, which is weaker and heavier, in commercial products such as bicycle frames, golf clubs and airplane bodies.   Even further in the future, the nanothreads could perhaps stretch into space to deliver supplies to the International Space Station or interact with orbiting satellites. Seriously. Futurists have long imagined that a cable anchored on Earth and attached to a satellite in orbit could be the basis for a space elevator, but making a cable long and strong enough to resist the high-altitude winds and to ferry loads safely has proved a challenge. Conventional steel cables would break under their own weight. Diamond nanothreads could in principle be both light enough and tough enough to do the job.   Even if this particular nanothread proves incapable of sending supplies or humans into orbit, its discovery could pave the way for better alternatives. This is not the first time scientists have spawned diamond structures by tricking rings of carbon into unique configurations. Diamond-like carbons, also called amorphous carbons, are typically applied as coatings to other materials, such as the protective layer on a stainless steel pan. Gogotsi says that although hitting upon a new structure is surprising and interesting, this research reminds chemists that the discovery of other similar structures is not far off. “This group has shown that it’s another member of the family of diamond structures, and I’m sure that it’s not the last,” Gogotsi says. If so, then someday a space elevator may exist, and there might really be diamonds in the sky.