Title :
Transport Gap in Dual-Gated Graphene Bilayers Using Oxides as Dielectrics
Author :
Kayoung Lee ; Fallahazad, Babak ; Hongki Min ; Tutuc, Emanuel
Author_Institution :
Microelectron. Res. Center, Univ. of Texas, Austin, TX, USA
Abstract :
Graphene bilayers in Bernal stacking exhibit a transverse electric (E) field-dependent band gap, which can be used to increase the channel resistivity and enable higher on/off ratio devices. We provide a systematic investigation of transport characteristics in dual-gated graphene bilayer devices as a function of density and E field and at temperatures from room temperature down to 0.3 K. The sample conductivity shows finite threshold voltages along the electron and hole branches, which increase as the E field increases, similar to a gapped semiconductor. We extract the transport gap as a function of E field and discuss the impact of disorder. In addition, we show that beyond the threshold, the bilayer conductivity shows a highly linear dependence on density, which is largely insensitive to the applied E field and the temperature.
Keywords :
dielectric materials; electrical conductivity; graphene; multilayers; semiconductor materials; Bernal stacking; C; bilayer conductivity; channel resistivity; dielectrics; dual-gated graphene bilayers; electron branch; finite threshold voltages; gapped semiconductor; hole branch; on/off ratio devices; oxides; transport gap; transverse electric field-dependent band gap; Conductivity; Logic gates; Photonic band gap; Temperature dependence; Temperature measurement; Threshold voltage; Bilayer; graphene; transport gap;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2012.2228203
