Provided are a semiconductor device and a method for manufacturing same. The device comprises: a substrate, a first insulating layer on the substrate, a plurality of trenches formed in the substrate, a nucleation layer arranged on one side wall of each trench, and a first semiconductor layer formed along the trenches by means of the nucleation layer. The present disclosure facilitates the achievement of one of the following effects: achieving a high height-width ratio and a high integration density, reducing an on-resistance, improving a threshold voltage, achieving a normally-off state, and providing a semiconductor device that has a high power and a high reliability, is suitable for a planarization process, is provided with an easy preparation method, and reduces costs.

A method of manufacturing a semiconductor integrated circuit includes forming a body region having a second conductivity type in an upper portion of a support layer having a first conductivity type and forming a well region having a second conductivity type in an upper portion of the support layer. An output side buried layer is formed inside the body region and a circuit side buried layer is formed inside the well region. A trench is dug to penetrate through the body region and a control electrode structure is buried in the gate trench. First and second terminal regions are formed on the well region and an output terminal region is formed on the body region. An output stage element having the output terminal region is controlled by a circuit element including the first and second terminal regions.

A method of microfabrication includes epitaxially growing a first vertical channel structure of silicon-containing material on a first sacrificial layer of silicon containing material, the first sacrificial layer having etch selectivity with respect to the vertical channel structure. A core opening is directionally etched through the vertical channel structure to expose the first sacrificial layer, and the first sacrificial layer is isotropically etched through the core opening to form a first isolation opening for isolating the first vertical channel structure.

A method of microfabrication includes forming an initial vertical channel structure of semiconductor material protruding from a surface of a substrate such that the initial vertical channel structure has a current flow path that is perpendicular to the surface of the substrate. The initial vertical channel structure is segmented lengthwise into a plurality of independent vertical channel structure segments, each vertical channel structure segment having a respective current flow path that is perpendicular to the surface of the substrate.

A semiconductor device structure and a method for fabricating the semiconductor device structure are disclosed. The method includes receiving a substrate stack including at least one semiconductor fin, the substrate stack including: a bottom source/drain epi region directly below the semiconductor fin; a vertical gate structure directly above the bottom source/drain epi region and in contact with the semiconductor fin; a first inter-layer dielectric in contact with a sidewall of the vertical gate structure; and a second interlayer-layer dielectric directly above and contacting a top surface of the first inter-layer dielectric. The method further including: etching a top region of the semiconductor fin and the gate structure thereby creating a recess directly above the top region of the semiconductor fin and the vertical gate structure; and forming in the recess a top source/drain epi region directly above, and contacting, a top surface of the semiconductor fin.

A vertical field effect transistor includes a first epitaxial region in contact with a top surface of a channel fin extending vertically from a bottom source/drain located above a substrate, a second epitaxial region above the first epitaxial region having a horizontal thickness that is larger than a horizontal thickness of the first epitaxial region. The first epitaxial region and the second epitaxial region form a top source/drain region of the semiconductor structure. The first epitaxial region has a first doping concentration and the second epitaxial region has a second doping concentration that is lower than the first doping concentration. A top spacer, adjacent to the first epitaxial region and the second epitaxial region, is in contact with a top surface of a high-k metal gate stack located around the channel fin and in contact with a top surface of a first dielectric layer disposed between adjacent channel fins.

A semiconductor device is provided. The semiconductor device includes a bottom epitaxial layer, a gate stack formed over the bottom epitaxial layer, the gate stack including a work function metal (WFM) layer, a channel fin formed on the bottom epitaxial layer, a first interlayer dielectric (ILD) layer formed in a gate landing area over the gate stack, a second ILD layer formed in an area other than the gate landing area, and a WFM encapsulation layer formed between the first ILD layer and the second ILD layer, and formed on sidewalls of the gate stack.

Epitaxially grow first lower source-drain regions within a substrate. Portions of the substrate adjacent the lower regions are doped to form second lower source-drain regions. An undoped silicon layer is formed over the first and second lower regions. Etch completely through the undoped layer into the first and second lower regions to form fins and to define bottom junctions beneath the fins. The fins and bottom junctions define intermediate cavities. Form lower spacers, gates, and upper spacers in the cavities; form top junctions on outer surfaces of the fins; and form epitaxially grown first upper source-drain regions outward of the upper spacers and opposite the first lower regions. The first upper regions are doped the same as the first lower regions. Form second upper source-drain regions outward of the upper spacers and opposite the second lower regions; these are doped the same as the second lower regions.

An integrated circuit structure includes a first semiconductor fin extending horizontally in a length direction and including a bottom portion and a top portion above the bottom portion, a bottom transistor associated with the bottom portion of the first semiconductor fin, a top transistor above the bottom transistor and associated with the top portion of the first semiconductor fin, and a first vertical diode. The first vertical diode includes: a bottom region associated with at least the bottom portion of the first semiconductor fin, the bottom region including one of n-type and p-type dopant; a top region associated with at least the top portion of the first semiconductor fin, the top region including the other of n-type and p-type dopant; a bottom terminal electrically connected to the bottom region; and a top terminal electrically connected to the top region at the top portion of the first semiconductor fin.

A semiconductor device with C-shaped channel portion and an electronic apparatus including the semiconductor device are disclosed. According to the embodiments, the semiconductor device may include a first semiconductor element and a second semiconductor element adjacent in a first direction. The first semiconductor element and the second semiconductor element may respectively include: a channel portion on a substrate, the channel portion including a curved nano-sheet or nano-wire with a C-shaped section; source/drain portions at upper and lower ends of the channel portion with respect to the substrate, respectively; and a gate stack surrounding a periphery of the channel portion. The channel portion of the first semiconductor element and the channel portion of the second semiconductor element may be substantially coplanar.