A method includes forming a device above an active region defined in a semiconducting substrate. The device includes a first gate structure, a first spacer formed adjacent the first gate structure, and first conductive source/drain contact structures positioned adjacent the first gate structure and separated from the first gate structure by the first spacer. A first portion of the first conductive source/drain contact structures is recessed at a first axial position along the first gate structure to define a first cavity. A second portion of the first conductive source/drain contact structures is recessed at a second axial position along the gate structure to define a second cavity. A dielectric cap layer is formed in the first and second cavities. A first conductive contact contacting the first gate structure in the first axial position is formed.

A nanowire transistor includes undoped source and drain regions electrically coupled with a channel region. A source stack that is electrically isolated from a gate conductor includes an interfacial layer and a source conductor, and is coaxially wrapped completely around the source region, extending along at least a portion of the source region. A Schottky barrier between the source conductor and the source region is a negative Schottky barrier and a concentration of free charge carriers is induced in the semiconductor source region.

A semiconductor device includes a semiconductor layer, first gate electrode, second gate electrode, first conductive layer and second conductive layer. The semiconductor layer includes a first side surface, a second side surface, a first end portion, and a second end portion. The first side surface and the second side surface face each other. The first end portion and the second end portion face each other. A first gate insulating layer is provided between the first gate electrode and the first side surface. A second gate insulating layer is provided between the second gate electrode and the second side surface. A first metal oxide layer is provided between the first conductive layer and the first end portion. A second metal oxide layer is provided between the second conductive layer and the second end portion.

A semiconductor device includes a silicon semiconductor layer including at least one region doped with a first conductive type dopant, a metal material layer electrically connected to the doped region, and a self-assembled monolayer (SAM) between the doped region and the metal material layer, the SAM forming a molecular dipole on an interface of the silicon semiconductor layer in a direction of reducing a Schottky barrier height (SBH).

An electrical device in which an interface layer is disposed in between and in contact with a conductor and a semiconductor.

A semiconductor structure containing a vertical Schottky contact transistor is provided in which the contact resistance as well as the junction resistance is improved. The vertical Schottky contact transistor includes a bottom Schottky contact source/drain structure and a top Schottky contact source/drain structure located at opposing ends of a semiconductor channel region. The bottom Schottky contact source/drain structure includes a base portion and a vertically extending portion.

A nanowire transistor includes undoped source and drain regions electrically coupled with a channel region. A source stack that is electrically isolated from a gate conductor includes an interfacial layer and a source conductor, and is coaxially wrapped completely around the source region, extending along at least a portion of the source region. A Schottky barrier between the source conductor and the source region is a negative Schottky barrier and a concentration of free charge carriers is induced in the semiconductor source region.

Disclosed is a technique capable of reducing loss at the time of switching in a diode. A diode disclosed in the present specification includes a cathode electrode, a cathode region made of a first conductivity type semiconductor, a drift region made of a low concentration first conductivity type semiconductor, an anode region made of a second conductivity type semiconductor, an anode electrode made of metal, a barrier region formed between the drift region and the anode region and made of a first conductivity type semiconductor having a concentration higher than that of the drift region, and a pillar region formed so as to connect the barrier region to the anode electrode and made of a first conductivity type semiconductor having a concentration higher than that of the barrier region. The pillar region and the anode are connected through a Schottky junction.

A semiconductor device may include an n type layer disposed at a first surface of an n+ type silicon carbide substrate; a p type region, a p type region, an n+ type region, and a p+ type region disposed at an upper portion in the n type layer; a gate electrode and a source electrode disposed on the n type layer and insulated from each other; and a drain electrode disposed at a second surface of the n+ type silicon carbide substrate, wherein the source electrode is in contact with the p type region, the n+ type region, and the p+ type region, and the source electrode may include an ohmic junction region disposed at a contact portion of the source electrode and the n+ type region and the contact portion of the source region and the p+ type region and a Schottky junction region disposed at the contact portion of the source electrode and the p type region.

A semiconductor device according to the present invention includes a semiconductor chip having a semiconductor layer that has a first surface on a die-bonding side, a second surface on the opposite side of the first surface, and an end surface extending in a direction crossing the first surface and the second surface, a first electrode that is formed on the first surface and has a peripheral edge at a position separated inward from the end surface, and a second electrode formed on the second surface, a conductive substrate onto which the semiconductor chip is die-bonded, a conductive spacer that has a planar area smaller than that of the first electrode and supports the semiconductor chip on the conductive substrate, and a resin package that seals at least the semiconductor chip and the conductive spacer.