Gate-all-around integrated circuit structures having high mobility, and methods of fabricating gate-all-around integrated circuit structures having high mobility, are described. For example, an integrated circuit structure includes a silicon nanowire or nanoribbon. An N-type gate stack is around the silicon nanowire or nanoribbon, the N-type gate stack including a compressively stressing gate electrode. A first N-type epitaxial source or drain structure is at a first end of the silicon nanowire or nanoribbon. A second N-type epitaxial source or drain structure is at a second end of the silicon nanowire or nanoribbon. The silicon nanowire or nanoribbon has a <110> plane between the first N-type epitaxial source or drain structure and the second N-type epitaxial source or drain structure.

An ohmic contact for a multiple channel FET comprises a plurality of slit-shaped recesses in a wafer on which a multiple channel FET resides, with each recess having a depth at least equal to the depth of the lowermost channel layer. Ohmic metals in and on the sidewalls of each recess provide ohmic contact to each of the multiple channel layers. An ohmic metal-filled linear connecting recess contiguous with the outside edge of each recess may be provided, as well as an ohmic metal contact layer on the top surface of the wafer over and in contact with the ohmic metals in each of the recesses. The present ohmic contact typically serves as a source and/or drain contact for the multiple channel FET. Also described is the use of a regrown material to make ohmic contact with multiple channels, with the regrown material preferably having a corrugated structure.

A semiconductor device includes a substrate, a gate structure on the substrate, and a gate contact in the gate structure. The gate structure includes a gate electrode extending in a first direction and a gate capping pattern on the gate electrode. The gate contact is connected to the gate electrode. The gate electrode includes a protrusion extending along a boundary between the gate contact and the gate capping pattern.

The present application discloses a method for manufacturing a high-voltage metal gate device. After the deposition of a gate metal through a normal process, in CMP processes performed to the gate metal, firstly a first CMP process is performed to thin the gate metal to a certain thickness in advance, then a blocking dielectric layer is deposited, a large-area high-voltage gate region is opened through photolithography, and the blocking dielectric layer other than the blocking dielectric layer in the large-area high-voltage gate region is removed through etching. In a second CMP process performed to the gate metal, due to the blocking dielectric layer on the surface of the large-area gate metal in the high-voltage gate region, the polishing speed is slow, and CMP dishing will not be caused.

Apparatus and methods are disclosed, including an apparatus that includes a number of tiers of a first semiconductor material, each tier including at least one access line of at least one memory cell and at least one source, channel and/or drain of at least one peripheral transistor, such as one used in an access line decoder circuit or a data line multiplexing circuit. The apparatus can also include a number of pillars of a second semiconductor material extending through the tiers of the first semiconductor material, each pillar including either a source, channel and/or drain of at least one of the memory cells, or a gate of at least one of the peripheral transistors. Methods of forming such apparatus are also described, along with other embodiments.

A method of forming a vertical fin field effect transistor (vertical finFET) with two concentric gate structures, including forming one or more tubular vertical fins on a substrate, forming a first gate structure around an outer wall of at least one of the one or more tubular vertical fins, and forming a second gate structure within an inner wall of at least one of the one or more tubular vertical fins having the first gate structure around the outer wall.

One illustrative method disclosed includes, among other things, forming a sacrificial S/D contact structure above an S/D region of a transistor device, removing at least a portion of a gate cap and at least a portion of a gate sidewall spacer to define a gate contact cavity that is positioned entirely above the active region and exposes an upper surface of a gate structure of the transistor device, and forming an internal sidewall spacer within the gate contact cavity. The method also includes performing at least one process operation to remove at least the sacrificial S/D contact structure and define a S/D contact cavity, and forming a gate contact structure within the gate contact cavity that is conductively coupled to the gate structure and forming a S/D contact structure within the S/D contact cavity that is conductively coupled to the S/D region.

An integrated circuit includes a first diffusion area for a first type transistor. The first type transistor includes a first drain region and a first source region. A second diffusion area for a second type transistor is separated from the first diffusion area. The second type transistor includes a second drain region and a second source region. A gate electrode continuously extends across the first diffusion area and the second diffusion area in a routing direction. A first metallic structure is electrically coupled with the first source region. A second metallic structure is electrically coupled with the second drain region. A third metallic structure is disposed over and electrically coupled with the first and second metallic structures. A width of the first metallic structure is substantially equal to or larger than a width of the third metallic structure.

A method of manufacturing semiconductor device includes forming a plurality of sacrificial layers and a plurality of semiconductor layers repeatedly and alternately stacked on a substrate, partially removing the sacrificial layers, forming spacers in removed regions of the sacrificial layers, and replacing remaining portions of the sacrificial layers with a gate electrode. Each of the sacrificial layers includes first portions disposed adjacent to the plurality of semiconductor layers and a second portions disposed between the first portions. The second portion having a different composition from the first portions.

Resistance of a FINFET is reduced while performance of an element is prevented from being deteriorated due to an increase in stress, thereby performance of a semiconductor device is improved. When a memory cell formed on an upper side of a first fin and an n transistor formed on an upper side of a second fin are mounted on the same semiconductor substrate, the surface of the first fin having a source/drain region of the memory cell is covered with a silicide layer, and part of a source/drain region of the n transistor is formed of an epitaxial layer covering the surface of the second fin.