Fig. 4 Transfer characteristics of the carristor.

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Fig. 4 Transfer characteristics of the carristor. Transfer characteristics of the carristor. (A) Room temperature semilog ITB-VG transfer characteristics of an MIS-C at VTB = −0.5 V. Inset: The corresponding linear scale ITB-VG at various VTB. (B) Fermi level shift of graphene versus VG. These data are extracted from VG-dependent surface potential variations and converted by applying the Schottky-Mott model based on the following expression: φs = WG + ΔEFG − Ws (where Ws is the WS2 work function). Inset: Energy band diagram under different gate polarities. Effect of p-doping (top; VG < 0); the shifting of EFG to a lower level results in φs forming an inversion layer; thus, ITB is dominated by holes. Effect of n-doping (bottom; VG > 0); the shifting of EFG to an upper level results in φs forming an accumulation of electrons; ITB is dominated by the abundance of electrons. (C) In-plane resistivity as a function of the gate voltage in an MGr channel FET measured at VSD = 10 mV under room temperature. Insets: Output curve of the same device at a back-gate voltage VBG = 20 V (bottom) and an optical image of a 10-nm-thick MGr with source/drain (S/D) contact (top right). (D) On/off ratio versus temperature for carristors and barristors. Inset: Plot of ln(G) versus 1000 T−1 for an MIS-C at on and off states, where conductance G is defined as 1/ρT. The barristor data are extracted from previous studies (5, 6, 9, 11). Dongil Chu et al. Sci Adv 2017;3:e1602726 Copyright © 2017, The Authors