Devices, structures, and methods thereof for providing a Schottky or Schottky-like contact as a source region and/or a drain region of a power transistor are disclosed. A power transistor structure comprises a substrate of a first dopant polarity, a drift region formed on or within the substrate, a body region formed on or within the drift region, a gate structure formed on or within the substrate, a source region adjacent to the gate structure, a drain region formed adjacent to the gate structure. At least one of the source region and the drain region is formed from a Schottky or Schottky-like contact substantially near a surface of the substrate, comprising a silicide layer and an interfacial dopant segregation layer. The Schottky or Schottky-like contact is formed by low-temperature annealing a dopant segregation implant in the source and/or drain region.

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 flash memory device and its manufacturing method are presented. The flash memory device includes a substrate; a memory unit on the substrate, comprising a channel structure, wherein the channel structure comprises, sequentially from inner to outer of the channel structure, a channel layer comprising a first component substantially perpendicular to an upper surface of the substrate and a second component on the first component, a tunnel insulation layer wrapped around the channel layer, a charge capture layer wrapped around the tunnel insulation layer, and a blocking layer wrapped around the charge capture layer; a plurality of gate structures wrapped around the channel structure and arranged along a symmetry axis of the channel structure with a topmost gate structure wrapped around the second component; and a channel contact component connecting to, and forming a Schottky contact with, the second component of the channel layer. This device reduces the leakage current.

A method includes forming a first sacrificial layer over a substrate, and forming a sandwich structure over the first sacrificial layer. The sandwich structure includes a first isolation layer, a two-dimensional material over the first isolation layer, and a second isolation layer over the two-dimensional material. The method further includes forming a second sacrificial layer over the sandwich structure, forming a first source/drain region and a second source/drain region on opposing ends of, and contacting sidewalls of, the two-dimensional material, removing the first sacrificial layer and the second sacrificial layer to generate spaces, and forming a gate stack filling the spaces.

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

An electronic device includes first and second electrodes that are spaced apart from each other and a 2D material layer. The 2D material layer connects the first and second electrodes. The 2D material layer includes a plurality of 2D nanomaterials. At least some of the 2D nanomaterials overlap one another.

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.

A Schottky contact structure for a semiconductor device having a Schottky contact and an electrode for the contact structure disposed on the contact. The Schottky contact comprises: a first layer of a first metal in Schottky contact with a semiconductor; a second layer of a second metal on the first layer; a third layer of the first metal on the second layer; and a fourth layer of the second metal on the third layer. The electrode for the Schottky contact structure disposed on the Schottky contact comprises a third metal, the second metal providing a barrier against migration between the third metal and the first metal.

A device includes a first gate structure positioned above an active region defined in a semiconducting substrate. A first spacer is positioned adjacent the first gate structure. First conductive source/drain contact structures are positioned adjacent the first gate structure and separated from the first gate structure by the first spacer. A first recessed portion of the first conductive source/drain contact structures is positioned at a first axial position along the first gate structure. A second recessed portion of the first conductive source/drain contact structures is positioned at a second axial position along the gate structure. A dielectric cap layer is positioned above the first and second recessed portions. A first conductive contact contacts the first gate structure in the first axial position. The dielectric cap layer above the first recessed portion is positioned adjacent the first conductive contact.

The field effect transistor (FET) of the present subject matter comprises a bottom gate electrode, a bottom gate dielectric provided on the bottom gate electrode, a channel layer provided on the bottom gate dielectric. A top portion comprising a source electrode, a drain electrode, a top gate electrode provided, and a top dielectric layer is provided on the channel layer. The channel layer forms Schottky barriers at points of contact with the source and the drain electrode. A back-gate voltage varies a height and a top-gate voltage varies a width of the Schottky barrier. The FET can be programmed to work in two operating modes-tunnelling (providing low power consumption) and thermionic mode (providing high performance). The FET can also be programmed to combine the tunnelling and thermionic mode in a single operating cycle, yielding high performance with low power consumption.