Lund University / Delft University of Technology / Stanford University / IBM TJ Watson Research Center / University of Wisconsin / Max Planck Institute / Hall effect10 / 11 / /
IndustryTerm
energy levels / transistor applications / linear energy / silicon devices / energy gap / metal contacts / low-melting-point metal / frequency applications / electronic devices / low-energy electronic band structure / chemical vapour deposition / ballistic graphene electronics / computer chips / Metal electrodes / high carrier mobility / graphene devices / carrier densities / low-energy electronic structure / graphene device / electron energy / energy / /
OperatingSystem
Fermi / /
Organization
Max Planck Institute in Stuttgart / Rutgers / National Center for High Resolution Electron Microscopy / Stanford University / EPFL / Delft University of Technology / Lund University / University of Wisconsin / /
Person
Charles Frank / Santiago Calatrava / Philip Kim / Marcus Freitag / /
NEWS & VIEWS Graphene Nanoelectronics goes flat out The unique electronic band structure of graphene has led to a number of exotic effects that have fascinated fundamental researchers and may also lead to improvements in