A semiconductor structure includes a substrate and an intrinsic replacement channel. A tunneling field effect transistor (TFET) fin may be formed by the intrinsic replacement channel, a p-fin and an n-fin formed upon the substrate. The p-fin may serve as the source of the TFET and the n-fin may serve as the drain of the TFET. The replacement channel may be formed in place of a sacrificial channel of a diode fin that includes the p-fin, the n-fin, and the sacrificial channel at the p-fin and n-fin junction.

Methods are provided for fabricating a semiconductor junction. A first semiconductor structure is selectively grown in a nanotube, which extends laterally over a substrate, from a seed extending within the nanotube. The seed is removed to expose the first semiconductor structure and create a cavity in the nanotube. A second semiconductor structure is selectively grown in the cavity from the first semiconductor structure, thereby forming a semiconductor junction between the first and second structures.

An electrical circuit is disclosed that comprises plurality of tunneling field-effect transistors (TFETs) arranged in a diffusion network matrix having a plurality of nodes wherein, for each of the TFETs that is not on an end of the matrix, a drain of the TFET is electrically coupled with the source of at least one of the other TFETs at a node of the matrix and a source of the TFET is electrically coupled with the drain of at least one of the other TFETs at another node of the matrix. The electrical circuit further comprises a plurality of capacitors, wherein a respective one of the plurality of capacitors is electrically coupled with each node that includes the source of at least one TFET and the drain of at least one TFET. The TFETs may be symmetrical graphene-insulator-graphene field-effect transistors (SymFETs), for example.

A synchronous rectifier is described that includes a transistor device that has a gate terminal, a source terminal, a drain terminal, and a field-plate electrode. The field-plate electrode of the transistor device includes an integrated diode. The integrated diode is configured to discharge a parasitic capacitance of the transistor device during each switching operation of the synchronous rectifier. In some examples, the integrated diode is also configured to charge the parasitic capacitance of the transistor device during each switching operation of the synchronous rectifier.

A semiconductor device formed in a semiconductor substrate includes a source region, a drain region, a gate electrode, and a body region disposed between the source region and the drain region. The gate electrode is disposed adjacent at least two sides of the body region, and the source region and the gate electrode are coupled to a source terminal. A width of the body region between the two sides of the body region is selected so that the body region is configured to be fully depleted.

A two-dimensional (2D) heterojunction interlayer tunneling field effect transistor (Thin-TFET) allows for particle tunneling in a vertical stack comprising monolayers of two-dimensional semiconductors separated by an interlayer. In some examples, the two 2D materials may be misaligned so as to influence the magnitude of the tunneling current, but have a modest impact on gate voltage dependence. The Thin-TFET can achieve very steep subthreshold swing, whose lower limit is ultimately set by the band tails in the energy gaps of the 2D materials produced by energy broadening. These qualities in turn make the Thin-TFET an ideal low voltage, low energy solid state electronic switch.

A fin tunnel field effect transistor includes a seed region and a first type region disposed above the seed region. The first type region includes a first doping. The fin tunnel field effect transistor includes a second type region disposed above the first type region. The second type region includes a second doping that is opposite the first doping. The fin tunnel field effect transistor includes a gate insulator disposed above the second type region and a gate electrode disposed above the gate insulator. A method for forming an example fin tunnel field effect transistor is provided.

A semiconductor device comprising: an insulation substrate; an intrinsic semiconductor nanowire formed on the insulation substrate and having both ends doped in a p-type and an n-type, respectively and a region, which is not doped, between the doped region; doped region electrodes formed on each of the p-type doped region and the n-type doped region of the semiconductor nanowire; a lower insulation layer formed on an intrinsic region of the semiconductor nanowire; an intrinsic region electrode formed on a part of the lower insulation layer; and a metal or semiconductor nanoparticle region formed on the lower insulation layer and between the intrinsic region electrode and the doped region electrode and spaced apart from the electrodes.

The present disclosure relates to semiconductor structures and, more particularly, to a symmetric tunnel field effect transistor and methods of manufacture. The structure includes a gate structure including a source region and a drain region both of which comprise a doped VO.sub.2 region.

A structure and method for fabricating a vertical heterojunction tunnel field effect transistor (TFET) using limited lithography steps is disclosed. The fabrication of a second conductivity type source/drain region may utilize a single lithography step to form a first-type source/drain region, and a metal contact thereon, adjacent to a gate stack having a first conductivity type source/drain region on an opposite side.