A vertical tunneling FET (TFET) provides low-power, high-speed switching performance for transistors having critical dimensions below 7 nm. The vertical TFET uses a gate-all-around (GAA) device architecture having a cylindrical structure that extends above the surface of a doped well formed in a silicon substrate. The cylindrical structure includes a lower drain region, a channel, and an upper source region, which are grown epitaxially from the doped well. The channel is made of intrinsic silicon, while the source and drain regions are doped in-situ. An annular gate surrounds the channel, capacitively controlling current flow through the channel from all sides. The source is electrically accessible via a front side contact, while the drain is accessed via a backside contact that provides low contact resistance and also serves as a heat sink. Reliability of vertical TFET integrated circuits is enhanced by coupling the vertical TFETs to electrostatic discharge (ESD) diodes.

A transistor structure disposed on a substrate includes a gate electrode, an organic semiconductor layer, a gate insulation layer and a patterned metal layer. The gate insulation layer is disposed between the gate and the organic semiconductor layer. The patterned metal layer has a conductive oxidation surface and is divided into a source electrode and a drain electrode. A portion of the organic semiconductor layer is exposed between the source electrode and the drain electrode. The conductive oxidation surface directly contacts with the organic semiconductor layer.

A structure and a method of fabrication are disclosed of a high voltage junctionless field effect device. A channel layer and a barrier layer are formed sequentially underneath the gate structure. The width of energy band gap of the barrier layer is wider than that of the channel layer. Thus the two dimensional electron gas (2-DEG) generated in the interface between the channel layer and the barrier layer of this junctionless field effect device has higher electron mobility. The structure of the device of this disclosure has a higher breakdown voltage which is advantageous for a high voltage junctionless field device. The structure offers advantages in device performance and reliability.

A method for fabricating floating body memory cells (FBCs), and the resultant FBCs where gates favoring different conductivity type regions are used is described. In one embodiment, a p type back gate with a thicker insulation is used with a thinner insulated n type front gate. Processing, which compensates for misalignment, which allows the different oxide and gate materials to be fabricated is described.

A silicon carbide semiconductor device includes a silicon carbide substrate, a gate insulating film, a gate electrode, an interlayer insulating film, and a gate interconnection. The silicon carbide substrate includes: a first impurity region; a second impurity region provided on the first impurity region; and a third impurity region provided on the second impurity region so as to be separated from the first impurity region. A trench has a side portion and a bottom portion, the side portion extending to the first impurity region through the third impurity region and the second impurity region, the bottom portion being located in the first impurity region. When viewed in across section, the interlayer insulating film extends from above the third impurity region to above the gate electrode so as to cover the corner portion.

A semiconductor memory device includes insulating patterns and conductive patterns stacked alternately with each other, penetrating structures passing through the insulating patterns and the conductive patterns, and deposition suppressing layers formed on one end portions of respective interfaces between the insulating patterns and the conductive patterns.

Semiconductor devices are provided. The semiconductor device includes a first fin portion and a second fin portion arranged on a substrate and extended in a first direction, the first fin portion and the second fin portion being spaced apart from each other in the first direction, a field insulating layer between the first fin portion and the second fin portion and having an upper surface thereof lower than an upper surface of the first fin portion, a first metal gate extended in a second direction on the first fin portion and a silicon gate extended in the second direction on the field insulating layer and contacting the field insulating layer.

Techniques for a semiconductor device are provided. Techniques are directed to forming a semiconductor device by: forming a fin structure in a substrate, forming a protective layer over an upper portion of the fin structure, the protective layer having an etch selectivity with respect to a material of the fin structure, and performing an undercut etch so as to remove a lower portion of the fin structure below the protective layer, thereby defining a nanowire structure from the fin structure.

A silicon-containing nucleation layer can be employed to provide a self-aligned template for selective deposition of tungsten within backside recesses during formation of a three-dimensional memory device. The silicon-containing nucleation layer may remain as a silicon layer, converted into a tungsten silicide layer, or replaced with a tungsten nucleation layer. Tungsten deposition can proceed only on the surface of the silicon-containing nucleation layer or a layer derived therefrom in a subsequent tungsten deposition process.

A semiconductor component, which includes a substrate, an interfacial layer disposed on the substrate, a first metal gate structure and a second metal gate structure disposed on the substrate. The first metal gate structure includes a first high-k dielectric layer disposed on the interfacial layer, and a first metal gate layer disposed on the first high-k dielectric layer. The second metal gate structure includes a second high-k dielectric layer disposed on the interfacial layer, a third high-k dielectric layer disposed on the second high-k dielectric layer, and a second metal gate layer disposed on the third high-k dielectric layer.