Graphene/fluorographene heterostructure for nano ribbon transistor channel

Abstract: 4H-SiC multilayer graphene/fluorographene heterostructures have been implemented to fabricate a 40 nm transistor channel. The plasma-assisted fluorination process with a carbon-tofluorine ratio of ∼1 allows the passivation of the sidewalls with a substantial reduction in the channel width to form multilayer graphene nanoribbons (GNRs). A graphene channel is completely embedded in the passivated top and sidewalls of graphene. the gate leakage is in the nanoampere range, which makes the fluorinated dielectric ro… Show more

“…23 While still intriguing as possible gate insulators or tunnel barriers they cannot be employed as 2D semiconductors. [24][25][26][27] A commonly employed strategy in the semiconductor industry is to alter the electronic properties of homonuclear lattices. In silicon, for example, heteroatoms are incorporated into the bulk lattice, which is typically referred to as ''impurity doping''.…”

Development of metal-free layered semiconductors for 2D organic field-effect transistors

“…23 While still intriguing as possible gate insulators or tunnel barriers they cannot be employed as 2D semiconductors. [24][25][26][27] A commonly employed strategy in the semiconductor industry is to alter the electronic properties of homonuclear lattices. In silicon, for example, heteroatoms are incorporated into the bulk lattice, which is typically referred to as ''impurity doping''.…”

Development of metal-free layered semiconductors for 2D organic field-effect transistors

Electronic and Thermoelectric Properties of Graphene on 4H-SiC (0001) Nanofacets Functionalized with F4-TCNQ

Direct Reconstruction of the Band Diagram of Rhombohedral-Stacked Bilayer WSe₂–Graphene Heterostructure via Photoemission Electron Microscopy