A semiconductor device includes an active region that extends on the substrate in a first direction; a plurality of semiconductor layers disposed on the active region and that are spaced apart from each other in a vertical direction perpendicular to an upper surface of the substrate; a gate structure disposed on the substrate and that crosses the active region and the plurality of semiconductor layers, surrounds each of the plurality of semiconductor layers, and extends in a second direction; a source/drain region disposed on at least one side of the gate structure and in contact with a portion of the plurality of semiconductor layers; and an epitaxial layer that is spaced apart from an uppermost semiconductor layer, is disposed below the source/drain region and between the active region and the source/drain region, and is in contact with at least a portion of the side surfaces of the lowermost semiconductor layer.

A triple-gate MOS transistor is manufactured in a semiconductor substrate including at least one active region laterally surrounded by electrically isolating regions. Trenches are etched on either side of an area of the active region configured to form a channel for the transistor. An electrically isolating layer is deposited on an internal surface of each of the trenches. Each of the trenches is then filled with a semiconductive or electrically conductive material up to an upper surface of the active region so as to form respective vertical gates on opposite sides of the channel. An electrically isolating layer is then deposited on the upper surface of the area of the active region at the channel of the transistor. At least one semiconductive or electrically conductive material then deposited on the electrically isolating layer formed at the upper surface of the active region to form a horizontal gate of the transistor.

A semiconductor structure includes a substrate; a gate structure located on the substrate extending along a first direction; a source/drain doped layer in the substrate located on two sides of the gate structure; and a conductive layer on the source/drain doped layer and covering a sidewall and a top surface of the source/drain doped layer.

The embodiments of the disclosure provide a FinFET. The FinFET includes a substrate, a first gate stack and a second gate stack. The substrate has a first fin and a second fin. The first gate stack is across the first fin and extends along a widthwise direction of the first fin. The second gate stack is across the second fin and extends along a widthwise direction of the second fin. A bottommost surface of the first gate stack is lower than a bottommost surface of the second gate stack, and a first gate height of the first gate stack directly on the first fin is substantially equal to a second gate height of the second gate stack directly on the second fin.

A semiconductor device includes a substrate provided with an electronic device, an interlayer dielectric (ILD) layer formed over the electronic device, a wiring pattern formed on the ILD layer and a contact formed in the ILD layer and physically and electrically connecting the wiring pattern to a conductive region of the electronic device. An insulating liner layer is provided on sidewalls of the contact between the contact and the ILD layer. A height of the insulating liner layer measured from a top of the conductive region of the electronic device is less than 90% of a height of the contact measured between the top of the conductive region and a level of an interface between the ILD layer and the wiring pattern.

A transistor structure includes a semiconductor body, a source region, a drain region and a gate region. The semiconductor body has a convex structure and the convex structure has at least four conductive channels extending upward. The source region contacts with a first end of the convex structure. The drain region contacts with a second end of the convex structure. The gate region has a gate conductive layer, wherein the gate conductive layer is across over the convex structure. Two or four conductive channels are not parallel to each other, and there is no shallow trench isolation region among the at least four conductive channels.

The present disclosure describes a structure including a fin field effect transistor (finFET) and a nano-sheet transistor on a substrate and a method of forming the structure. The method can include forming first and second vertical structures over a substrate, where each of the first and the second vertical structures can include a buffer region and a first channel layer formed over the buffer region. The method can further include disposing a masking layer over the first channel layer of the first and second vertical structures, removing a portion of the first vertical structure to form a first recess, forming a second channel layer in the first recess, forming a second recess in the second channel layer, and disposing an insulating layer in the second recess.

A method includes forming an active region on a substrate, forming a sacrificial gate stack engaging the active region, measuring a gate length of the sacrificial gate stack at a height lower than a top surface of the active region, selecting an etching recipe based on the measured gate length of the sacrificial gate stack, etching the sacrificial gate stack with the etching recipe to form a gate trench, and forming a metal gate stack in the gate trench.

A semiconductor device structure, along with methods of forming such, are described. The semiconductor device structure includes a gate electrode layer disposed over a substrate, a source/drain epitaxial feature disposed over the substrate, a first hard mask layer disposed over the gate electrode layer, and a contact etch stop layer (CESL) disposed over the source/drain epitaxial feature. The structure further includes a first interlayer dielectric (ILD) layer disposed on the CESL and a first treated portion of a second hard mask layer disposed on the CESL and the first ILD layer. A top surface of the first hard mask layer and a top surface of the first treated portion of the second mask layer are substantially coplanar. The structure further includes an etch stop layer disposed on the first hard mask layer and the first treated portion of the second mask layer.

A semiconductor device structure is provided. The semiconductor device structure includes an isolation layer formed over a substrate, and a plurality of nanostructures formed over the isolation layer. The semiconductor device structure includes a gate structure wrapped around the nanostructures, and an S/D structure wrapped around the nanostructures. The semiconductor device structure also includes a first oxide layer between the substrate and the S/D structure. The first oxide layer and the isolation layer are made of different materials, and the first oxide layer is in direct contact with the isolation layer, and a sidewall surface of the S/D structure is aligned with a sidewall surface of the first oxide layer.