Graphene's ability to conduct electricity has been found to be higher than any other known material at room temperature. The research shows that graphene, a single-atom-thick sheet of graphite that combines aspects of semiconductors and metals, is a promising replacement for conventional semiconductor materials such as silicon in applications ranging from high-speed computer chips to biochemical sensors. A team of researchers led by University of Maryland physics professor Michael S. Fuhrer of the university's Center for Nanophysics and Advanced Materials, and the Maryland NanoCenter said the findings are the first measurement of the effect of thermal vibrations on the conduction of electrons in graphene, and show that such vibrations have an extraordinarily small effect on the electrons. In any material, the energy associated with its temperature causes the atoms of the material to vibrate in place. As electrons travel through the material, they can bounce off these vibrating atoms, giving rise to electrical resistance. This electrical resistance is "intrinsic" to the material: it cannot be eliminated unless the material is cooled to absolute zero (-459.7 °F), and sets the upper limit to how well a material can conduct electricity. In graphene, the vibrating atoms at room temperature produce a resistivity ( a specific measure of resistance) that is about 35 percent less than the resistivity of copper, the lowest resistivity material known at room temperature. "Other extrinsic sources in today's fairly dirty graphene samples add some extra resistivity to graphene," said Fuhrer, "so the overall resistivity isn't quite as low as copper's at room temperature yet. However, graphene has far fewer electrons than copper, so in graphene the electrical current is carried by only a few electrons moving much faster than the electrons in copper." In semiconductors, a different measure, mobility, is used to quantify how fast electrons move. The limit to mobility of electrons in graphene is set by thermal vibration of the atoms and is about 200,000 cm2/Vs (centimeters squared per volt per second) at room temperature, compared to about 1400 cm2/Vs in silicon, and 77,000 cm2/Vs in indium antimonide, the highest mobility conventional semiconductor known. "Interestingly, in semiconducting carbon nanotubes, which may be thought of as graphene rolled into a cylinder, we've shown that the mobility at room temperature is over 100,000 cm2/Vs," said Fuhrer of research he and colleagues published in Nano Letters in 2004. Mobility determines the speed at which an electronic device (for instance, a field-effect transistor, which forms the basis of modern computer chips) can turn on and off. The very high mobility makes graphene promising for applications in which transistors much switch extremely fast, such as in processing extremely high frequency signals. Mobility can also be expressed as the conductivity of a material per electronic charge carrier, and so high mobility is also advantageous for chemical or biochemical sensing applications in which a charge signal from, for instance, a molecule adsorbed on the device, is translated into an electrical signal by changing the conductivity of the device. The results mean graphene is a very promising material for chemical and biochemical sensing applications. Its low resistivity and extremely thin nature also promises applications in thin, mechanically tough, electrically conducting, transparent films. Such films are needed in a variety of electronics applications from touch screens to photovoltaic cells. Fuhrer and coworkers showed that although the room-temperature limit of mobility in graphene is as high as 200,000 cm2/Vs, in present-day samples the actual mobility is lower, around 10,000 cm2/Vs, leaving significant room for improvement. Because graphene is only one atom thick, current samples must sit on a substrate, in this case silicon dioxide. Trapped electrical charges in the silicon dioxide (a sort of atomic-scale dirt) can affect the electrons in graphene and reduce the mobility. Also, vibrations of the silicon dioxide atoms themselves can also have an effect on the graphene which is stronger than the effect of graphene’s own atomic vibrations. This so-called "remote interfacial phonon scattering" effect is only a small correction to the mobility in a silicon transistor, but because the phonons in graphene itself are so ineffective at scattering electrons, this effect becomes very important in graphene. "We believe that this work points out the importance of these extrinsic effects, and creates a roadmap for finding better substrates for future graphene devices in order to reduce the effects of charged impurity scattering and remote interfacial phonon scattering," Fuhrer said. The research was published online this week in the journal Nature Nanotechnology.For more information, visit: www.umd.edu