The disclosure describes a tunneling field effect transistor having an overlapping structure between the source and drain regions providing a greater tunneling area. The source or drain region may be a doped region in a semi-conductive substrate. The other source or drain region may be formed by epitaxial deposition over the doped region. The gate is formed over the epitaxial region where the doped and epitaxial regions overlap. The doped region may be formed in a fin structure with the epitaxial region and gate being formed on the top and sides of the fin.

Double gated thin film transistors are described. In an example, an integrated circuit structure includes an insulator layer above a substrate. A first gate electrode is on the insulator layer, the first gate electrode having a non-planar feature. A first gate dielectric is on and conformal with the non-planar feature of the first gate electrode. A channel material layer is on and conformal with the first gate dielectric. A second gate dielectric is on and conformal with the channel material layer. A second gate electrode is on and conformal with the second gate dielectric. A first source or drain region is coupled to the channel material layer at a first side of the first gate dielectric. A second source or drain region is coupled to the channel material layer at a second side of the first gate dielectric.

The disclosure describes a tunneling field effect transistor having an overlapping structure between the source and drain regions providing a greater tunneling area. The source or drain region may be a doped region in a semi-conductive substrate. The other source or drain region may be formed by epitaxial deposition over the doped region. The gate is formed over the epitaxial region where the doped and epitaxial regions overlap. The doped region may be formed in a fin structure with the epitaxial region and gate being formed on the top and sides of the fin.

Described herein are various amorphous metal thin film transistors. Embodiments of such transistors include an amorphous metal gate electrode and a channel conductor formed on a non-conducting substrate. Further embodiments of such transistors include an amorphous metal source electrode, an amorphous metal drain electrode, and a channel conductor formed on a non-conducting substrate. Methods of forming such transistors are also described.

A TEFT includes a drain region on a substrate, a channel on the drain region, a dipole formation layer (DFL) on the channel, a dipole formation layer (DFL) on the channel, a source region on the DFL, a gate insulation pattern surrounding the channel, and a gate electrode surrounding the gate insulation pattern. The DFL contacts the channel and the source region and form dipoles between the channel and the source region.

After forming a trench extending through a sacrificial gate layer to expose a surface of a doped bottom semiconductor layer, a diode including a first doped semiconductor segment and a second doped semiconductor segment having a different conductivity type than the first doped semiconductor segment is formed within the trench. The sacrificial gate layer that laterally surrounds the first doped semiconductor segment and the second doped semiconductor segment is subsequently replaced with a gate structure to form a gated diode.

An apparatus comprising: a fermion source nanolayer (90); a first insulating nanolayer (92); a fermion transport nanolayer (94); a second insulating nanolayer (96); a fermion sink nanolayer (98); a first contact for applying a first voltage to the fermion source nanolayer; a second contact for applying a second voltage to the fermion sink nanolayer; and a transport contact for enabling an electric current via the fermion transport nanolayer. In a particular example, the apparatus comprises three graphene sheets (90, 94, 98) interleaved with two-dimensional Boron-Nitride (hBN) layers (92, 96).

A first of its kind polycrystalline or amorphous-based tunneling thin-film junction transistor (TJT) utilizing bipolar charge transport with a very high current density is introduced. Using the TJT architecture, this thin-film transistor (TFT) performs robustly at collector voltages at fields greater than 0.5 MV/cm with the current density output greater than 1 mA/mm without any observed electrical breakdown. Combining the principles of the tunneling emitter and the base inversion channel, the high-k dielectric/wideband gap amourphous or polycrystalline substrate/with p-type semiconductor substrate behaved most analogously to a bipolar transistor.

After forming a trench extending through a sacrificial gate layer to expose a surface of a doped bottom semiconductor layer, a diode including a first doped semiconductor segment and a second doped semiconductor segment having a different conductivity type than the first doped semiconductor segment is formed within the trench. The sacrificial gate layer that laterally surrounds the first doped semiconductor segment and the second doped semiconductor segment is subsequently replaced with a gate structure to form a gated diode.

After forming a trench extending through a sacrificial gate layer to expose a surface of a doped bottom semiconductor layer, a diode including a first doped semiconductor segment and a second doped semiconductor segment having a different conductivity type than the first doped semiconductor segment is formed within the trench. The sacrificial gate layer that laterally surrounds the first doped semiconductor segment and the second doped semiconductor segment is subsequently replaced with a gate structure to form a gated diode.