Title :
Epitaxial Graphene Transistors on SiC Substrates
Author :
Kedzierski, Jakub ; Hsu, Pei-Lan ; Healey, Paul ; Wyatt, Peter W. ; Keast, Craig L. ; Sprinkle, Mike ; Berger, Claire ; de Heer, Walt A.
Author_Institution :
Lincoln Lab., Massachusetts Inst. of Technol, Lexington, MA
Abstract :
This paper describes the behavior of top-gated transistors fabricated using carbon, specifically epitaxial graphene on SiC, as the active material. Although graphene devices have been built before, in this paper, we provide the first demonstration and systematic evaluation of arrays of a large number of transistors produced using standard microelectronics methods. The graphene devices presented feature high-k dielectric, mobilities up to 5000 cm2/Vldr s, and Ion/Ioff ratios of up to seven, and are methodically analyzed to provide insight into the substrate properties. Typical of graphene, these micrometer-scale devices have negligible band gaps and, therefore, large leakage currents.
Keywords :
carbon; carrier mobility; dielectric materials; nanostructured materials; transistors; C; SiC; SiC substrates; carrier mobility; epitaxial graphene transistors; graphene devices; high-k dielectric; leakage currents; micrometer-scale devices; standard microelectronics; top-gated transistors; transistor arrays; Carbon nanotubes; Dielectric materials; Dielectric substrates; High K dielectric materials; High-K gate dielectrics; Laboratories; Leakage current; Photonic band gap; Silicon carbide; Thin film transistors; $hbox{HfO}_{2}$ dielectric; Carbon devices; SiC; carbon transistors; epitaxial graphene; graphene; graphene devices; graphene transistors; high mobility; high- $k$ dielectric; semimetal; thin-film transistors;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2008.926593
