A semiconductor device includes a first electrode, a first conductive part, a semiconductor part, a second conductive part, a gate electrode and an insulating part. The first conductive part includes at least one of a metal, a metal oxide, or a metal nitride. The at least one of the metal, the metal oxide, or the metal nitride includes at least one selected from the group consisting of Ti, Ta, W, Cr, and Ru. The semiconductor part includes a first semiconductor region and a second semiconductor region. The first conductive part has a Schottky contact with the first semiconductor region. The second conductive part has a Schottky contact with the second semiconductor region. The second conductive part includes at least one selected from the group consisting of Pt, Ni, Ir, Pd, Au, and Co.

An interlayer is used to reduce Fermi-level pinning phenomena in a semiconductive device with a semiconductive substrate. The interlayer may be a rare-earth oxide. The interlayer may be an ionic semiconductor. A metallic barrier film may be disposed between the interlayer and a metallic coupling. The interlayer may be a thermal-process combination of the metallic barrier film and the semiconductive substrate. A process of forming the interlayer may include grading the interlayer. A computing system includes the interlayer.

A Schottky barrier device is provided herein that includes a TMD layer on a substrate, a graphene layer on the TMD layer, an electrolyte layer on the TMD layer, and a source gate contact on the electrolyte layer. A drain contact can be provided on the TMD layer and a source contact can be provided on the graphene layer. As ionic gating from the source gate contact and electrolyte layer is used to adjust the Schottky barrier height this Schottky barrier device can be referred to as an ionic control barrier transistor or ionic barristor.

This invention discloses a semiconductor device disposed in a semiconductor substrate. The semiconductor device includes a first semiconductor layer of a first conductivity type on a first major surface. The semiconductor device further includes a second semiconductor layer of a second conductivity type on a second major surface opposite the first major surface. The semiconductor device further includes an injection efficiency controlling buffer layer of a first conductivity type disposed immediately below the second semiconductor layer to control the injection efficiency of the second semiconductor layer.

A nonvolatile memory cell includes a first-conductivity-type silicon substrate, a metal layer formed in a surface of the first-conductivity-type silicon substrate, a second-conductivity-type diffusion layer formed in the surface of the first-conductivity-type silicon substrate and spaced apart from the metal layer, an insulating film disposed on the surface of the first-conductivity-type silicon substrate between the metal layer and the second-conductivity-type diffusion layer, a gate electrode disposed on the insulating film between the metal layer and the second-conductivity-type diffusion layer, and a sidewall disposed at a same side of the gate electrode as the metal layer and situated between the gate electrode and the metal layer, the sidewall being made of insulating material.

A method of forming a field effect transistor is provided. The method of forming a field effect transistor may include forming a dummy gate perpendicular to and covering a channel region of a semiconductor fin, such that a source drain region of the semiconductor fin remains uncovered, depositing a metal layer above and in direct contact with a sidewall of the dummy gate, and above and in direct contact with a top and a sidewall of the source drain region, and forming a metal silicide source drain in the source drain region by annealing the metal layer and the semiconductor fin, such that the metal silicide source drain overlaps the dummy gate.

A semiconductor device includes a MISFET having: a diamond substrate; a drift layer having a first layer with a first density for providing a hopping conduction and a second layer with a second density lower than the first density, and having a dope structure; a body layer on the drift layer; a source region in an upper portion of the body layer; a gate insulation film on a surface of the body layer; a gate electrode on a surface of the gate insulation film; a first electrode electrically connected to the source region and a channel region; and a second electrode electrically connected to the diamond substrate. The MISFET flows current in the drift layer in a vertical direction, and the current flows between the first electrode and the second electrode.

This invention discloses a semiconductor device disposed in a semiconductor substrate. The semiconductor device includes a first semiconductor layer of a first conductivity type on a first major surface. The semiconductor device further includes a second semiconductor layer of a second conductivity type on a second major surface opposite the first major surface. The semiconductor device further includes an injection efficiency controlling buffer layer of a first conductivity type disposed immediately below the second semiconductor layer to control the injection efficiency of the second semiconductor layer.

A process for manufacturing a Schottky barrier field-effect transistor is provided. The process includes: providing a structure including a control gate and a semiconductive layer positioned under the gate and having protrusions that protrude laterally with respect to the gate; anisotropically etching at least one of the protrusions by using the control gate as a mask, so as to form a recess in this protrusion, this recess defining a lateral face of the semiconductive layer; depositing a layer of insulator on the lateral face of the semiconductive layer; and depositing a metal in the recess on the layer of insulator so as to form a contact of metal/insulator/semiconductor type between the deposit of metal and the lateral face of the semiconductive layer.

An HEMT includes a gallium nitride layer. An aluminum gallium nitride layer is disposed on the gallium nitride layer. A gate is disposed on the aluminum gallium nitride layer. The gate includes a P-type gallium nitride and a schottky contact layer. The P-type gallium nitride contacts the schottky contact layer, and a top surface of the P-type gallium nitride entirely overlaps a bottom surface of the schottky contact layer. A protective layer covers the aluminum gallium nitride layer and the gate. A source electrode is disposed at one side of the gate, penetrates the protective layer and contacts the aluminum gallium nitride layer. A drain electrode is disposed at another side of the gate, penetrates the protective layer and contacts the aluminum gallium nitride layer. A gate electrode is disposed directly on the gate, penetrates the protective layer and contacts the schottky contact layer.