What exactly is graphene

Graphene is a form of carbon. As a material it is completely new – not only the thinnest ever but also the strongest. As a conductor of electricity it performs as well as copper. As a conductor of heat it outperforms all other known materials. It is almost completely transparent, yet so dense that not even helium, the smallest gas atom, can pass through it. Carbon, the basis of all known life on earth, has surprised us once again. Graphene consists of carbon atoms joined together in a flat lattice – similar to a honeycomb structure but just one atom thick. One millimeter of graphite actually consists of three million layers of graphene stacked on top of one another. The layers are weakly held together and are therefore fairly simple to tear off and separate. Anyone who has written something with an ordinary pencil has experienced this, and it is possible, when they did, that only a single layer of atoms, graphene, happened to end up on the paper. This is what happened when Andre Geim and Konstantin Novoselov used adhesive tape to rip off thin flakes from a larger piece of graphite in a more methodical manner. In the beginning they got flakes consisting of many layers of graphene, but when they repeated the tape-trick ten to twenty times the flakes got thinner and thinner. The next step was to find the miniscule fragments of graphene among the thicker layers of graphite and other carbon scraps. This is when they got their second brilliant idea: in order to be able to see the results of their meticulous work, the scientists from Manchester decided to attach the flakes to a plate of oxidized silicon, the standard working material in the semiconductor industry. Graphene has of course always existed; the crucial thing was to be able to spot it. Similarly, other naturally occurring forms of carbon have appeared before scientists when they viewed them in the right way: first nanotubes and then hollow balls of carbon, fullerenes (Nobel Prize in Chemistry 1996). Trapped inside graphite, graphene was waiting to be released. No-one really thought that it was possible. Many scientists thought that it would be impossible to isolate such thin materials: they would become crinkled or roll up at room temperature, or even simply completely vanish. In spite of this, some people still tried even though previous attempts to obtain graphene had failed. Formerly, it had been possible to obtain films with a thickness of less than 100 atoms – indeed, some had even been so thin that they were transparent. One way of obtaining graphene from graphite is to introduce chemical substances between the layers of atoms in order to weaken the bond between them and then subsequently separate the layers. Another method is to simply scratch away the layers of graphite. It was also tried, successfully, to “burn off” the silicon from silicon carbide crystals. At very high temperatures thin layers of carbon were left behind. Different techniques of epitaxial growth, used to create various semiconductor materials, are the most promising as regards producing graphene for use in the electronics industry. Rolls of 70 centimeter wide sheets of graphene are the largest produced so far..........

AWAITING DISCOVERY

Andre Geim and Konstantin Novoselov could only obtain micro flakes of the new material. Despite the miniscule size they could now begin to investigate the two most remarkable traits of graphene, which both influence its electrical properties. The first is the nearly perfect composition of graphene. The error-free ordering is due to the strong bonding of the carbon atoms. At the same time, the bonds are flexible enough to allow the web to stretch by up to 20% of its original size. The lattice also enables electrons to travel long distances in graphene without disturbance. In normal conductors, electrons often bounce like the ball in a pinball machine. This bouncing weakens the performance of the conductor. The other unique trait of graphene is that its electrons behave like particles of light, the massless photons, that in a vacuum relentlessly move ahead at a speed of 300 million meters per second. Similarly, electrons travelling in graphene behave as if they did not have any mass and move ahead at a constant speed of one million meters per second. This opens up the possibility of studying certain phenomena more easily on a smaller scale, i.e. without the use of a large particle accelerator. Graphene also allows scientists to test for some of the more ghost-like quantum effects that so far only have been discussed theoretically. One such phenomenon is a variant of Klein tunelling, which was formulated by the Swedish physicist Oskar Klein in 1929. The tunnel effect in quantum physics describes how particles can sometimes pass through a barrier that would normally block them. The larger the barrier the smaller the chance of quantum particles passing through. However, this does not apply to electrons travelling in graphene – in some circumstances they move ahead as if the barrier did not even exist.

DREAM WORLD

The possible practical applications for graphene have received much attention. So far, most of them exist only in our fantasies, but many are already being tested, also by Geim and Novoselov themselves. Graphene’s conducting ability has spurred a great deal of interest. Graphene transistors are predicted to be substantially faster than those made out of silicon today. In order for computer chips to become faster and more energy efficient they have to be smaller. Silicon hits a size boundary where the material ceases to function. The limit for graphene is even lower, so graphene components could be packed on a chip more tightly than today. One milestone was passed a few years ago when its key component, a graphene transistor, was presented that was as fast as its silicon counterpart. Maybe we are on the verge of yet another miniaturization of electronics that will lead to computers becoming even more efficient in the future. So far, graphene computers are nothing but a distant dream, although paper-thin transparent computer monitors that can be rolled up and carried in a hand bag have already appeared in commercials for tomorrow’s consumer electronics. In the meantime we can only speculate about some of the more and some of the less realistic applications, all still requiring significant initiatives with their outcomes still being uncertain. Since graphene is practically transparent (up to nearly 98%) while simultaneously being able to conduct electricity, it would be suitable for the production of transparent touch screens, light panels and maybe even solar cells. Also plastics could be made into electronic conductors if only 1% of graphene were mixed into them. Likewise by mixing in just a fraction of a per mill of graphene, the heat resistance of plastics would increase by 30 ˚C while at the same time making them more mechanically robust. This resilience could be utilised in new super strong materials, which are also thin, elastic and lightweight. In the future, satellites, airplanes, and cars could be manufactured out of the new composite materials. The perfect structure of graphene also makes it suitable for the production of extremely sensitive sensors that could register even the smallest levels of pollution. Even a single molecule adsorbed to the graphene surface would be discovered.

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