Title :
Enhancing Hysteresis in Graphene Devices Using Dielectric Screening
Author :
Brenner, Kevin ; Beck, T.J. ; Meindl, James D.
Author_Institution :
Nanoelectron. Res. Center, Georgia Inst. of Technol., Atlanta, GA, USA
Abstract :
A method of increasing hysteresis in graphene devices with a dielectric coating is presented. By controlling the sweep direction of the gate bias, “high-conductance” and “low-conductance” states can be produced by transitioning the device between dielectric screened and unscreened states, which is a fundamentally new approach to producing hysteresis. Moderate carrier densities (4 × 1012 cm-2) result in field-driven injection of charge from the graphene channel into the underlying SiO2 substrate, modifying the scattering charged-impurity layout seen by the graphene, ultimately disrupting the steady-state screening process. A stable room-temperature conductance gap of nearly one order of magnitude is demonstrated.
Keywords :
carrier density; dielectric materials; graphene; hysteresis; C; SiO2; conductance gap; dielectric coating; dielectric screened state; dielectric screening; dielectric unscreened state; gate bias; graphene channel; graphene devices; high conductance state; hysteresis; low conductance state; moderate carrier density; scattering charged-impurity layout; steady-state screening process; sweep direction; temperature 293 K to 298 K; Carbon; Coatings; Dielectrics; Hysteresis; Logic gates; Scattering; Substrates; Charged-impurity scattering; dielectric screening; graphene; graphene devices; hysteresis; memory;
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2012.2200650
