Physics Professor Publishes Paper on Graphene Research
May 12, 2015鈥擯rofessor of Jim Freericks鈥 paper, “Theory of Floquet band formation and local pseudospin textures in pump-probe photoemission of graphene,鈥 was recently accepted for by the open access journal . The paper explores the process of using lasers to control energy bands in graphene, an emerging material that could influence the way electronics are made.
Graphene has been called the thinnest and strongest substance known to science鈥攐ne million times thinner than paper. It鈥檚 an allotrope of carbon, meaning it is a structurally different form of the element, where the same atoms bond together in different ways. Graphene comprises a single layer of carbon atoms that are bonded together in a repeating pattern of hexagons. In 2010, two physicists at the University of Manchester won the for their pioneering research on graphene.
Freericks鈥 research focuses on how graphene鈥檚 electronic properties can be quickly modified鈥攊n a millionth of a billionth of a second, or a femtosecond鈥攂y using a laser.
鈥淸The project demonstrates] how one can control the way electrons move through a material at an extremely fast timescale鈥攁lmost one million times faster than a current computer processor鈥攂y shining light on it,鈥 Freericks explained.
and his collaborators used large-scale numerical simulations to predict how lasers can modify the properties of graphene (which are single-atom-thick sheets of carbon). Their findings may help scientists tune and control material properties with optical laser pulses, which could lead to new developments in electronics.
鈥淭his work has the potential to usher in a new era of designs for the extremely fast electronics of the future,鈥 Freericks said. 鈥淚 hope that this will lead鈥o even more advances that will greatly increase the speed of our computers by invoking novel design strategies and ultrafast switching.鈥
Freericks鈥 collaborators include Michael Sentef, Martin Claassen, Alexander Kemper, Brian Moritz, and Takashi Oka. The project was supported by the Department of Energy and Georgetown’s Robert L. McDevitt bequest.
Related Information
Freericks’ study was by SLAC National Accelerator Laboratory, a multi-program laboratory exploring questions in photon science, astrophysics, particle physics, and accelerator research. SLAC is operated by Stanford University for the Department of Energy’s Office of Science. SLAC featured Freericks’ research on May 27, 2015. “The results [of the study]…pave the way for experiments that create and control new states of matter with this specialized form of light, with potential applications in computing and other areas,” the organization wrote.