A semiconductor device is provided. The semiconductor device includes a substrate including an active pattern, a gate electrode extending in a first direction and crossing the active pattern which extends in a second direction, a separation structure crossing the active pattern and extending in the first direction, a first gate dielectric pattern disposed on a side surface of the gate electrode, a second gate dielectric pattern disposed on a side surface of the separation structure, and a gate capping pattern covering a top surface of the gate electrode. A level of a top surface of the separation structure is higher than a level of a top surface of the gate capping pattern.

A semiconductor device includes a first power supply line, a second power supply line, a first ground line, a switch circuit connected to the first and the second power supply line, and a switch control circuit connected to the first ground line and the first power supply line. The switch circuit includes a first and a second transistor of a first conductive type. A first gate electrode of the first transistor is connected to a second gate electrode of the second transistor. The switch control circuit includes a third transistor of a second conductive type, and a fourth transistor of a third conductive type. A third gate electrode of the third transistor is connected to a fourth gate electrode of the fourth transistor. A semiconductor device includes a signal line that electrically connects a connection point between the third and fourth transistor to the first and second gate electrode.

Integrated circuit structures having differential epitaxial source or drain dent are described. For example, an integrated circuit structure includes a first sub-fin structure beneath a first stack of nanowires or fin. A second sub-fin structure is beneath a second stack of nanowires or fin. A first epitaxial source or drain structure is at an end of the first stack of nanowires of fin, the first epitaxial source or drain structure having no dent or a shallower dent therein. A second epitaxial source or drain structure is at an end of the second stack of nanowires or fin, the second epitaxial source or drain structure having a deeper dent therein.

An integrated circuit structure includes a first vertical stack of horizontal nanowires or a first fin having a first lateral width. A first gate electrode is over the first vertical stack of horizontal nanowires or the first fin, the first gate electrode having a second lateral width. A second vertical stack of horizontal nanowires or a second fin is laterally spaced apart from the first vertical stack of horizontal nanowires or the second fin, the second vertical stack of horizontal nanowires or the second fin having a third lateral width, the third lateral width less than the first lateral width. A second gate electrode is over the second vertical stack of horizontal nanowires or the second fin, the second gate electrode laterally spaced apart from the first gate electrode, and the second gate electrode having a fourth lateral width, the fourth lateral width less than the second lateral width.

In some implementations, an apparatus may include a substrate having silicon. In addition, the apparatus may include a first layer of a source or drain region of a p-type transistor, the first layer positioned above the substrate, the first layer having boron, silicon and germanium. The apparatus may include a second layer coupled to the source or drain region, the second layer having a metal contact for the source or drain region. Moreover, the apparatus may include a third layer positioned between the first layer and the second layer, the third layer having at least one monolayer having gallium, where the third layer is adjacent to the first layer.

N-type gate-all-around (nanosheet, nanoribbon, nanowire) field-effect transistors (GAAFETs) vertically stacked on top of p-type GAAFETs in complementary FET (CFET) devices comprise non-crystalline silicon layers that form the n-type transistor source, drain, and channel regions. The non-crystalline silicon layers can be formed via deposition, which can provide for a simplified processing flow to form the middle dielectric layer between the n-type and p-type GAAFETs relative to processing flows where the silicon layers forming the n-type transistor source, drain, and channel regions are grown epitaxially.

A method includes forming a fin structure including first and second sacrificial layers and first and second channel layers over a substrate; forming a dummy gate structure across the fin structure; forming gate spacers on opposite sides of the dummy gate structure; forming first source/drain epitaxial layers on opposite sides of the first channel layer; forming second source/drain epitaxial layers on opposite sides of the second channel layer; removing the dummy gate structure and the first and second sacrificial layers to form a gate trench defined by the gate spacers; forming an oxynitride layer in the gate trench to surround the first channel layer; forming a dipole layer to surround the oxynitride layer; performing an anneal process to drive dipole dopants into the oxynitride layer; and depositing a high-k gate dielectric layer and a work function metal layer in the gate trench to form a gate structure.

An embodiment includes a method including forming an opening in a cut metal gate region of a metal gate structure of a semiconductor device, conformally depositing a first dielectric layer in the opening, conformally depositing a silicon layer over the first dielectric layer, performing an oxidation process on the silicon layer to form a first silicon oxide layer, filling the opening with a second silicon oxide layer, performing a chemical mechanical polishing on the second silicon oxide layer and the first dielectric layer to form a cut metal gate plug, the chemical mechanical polishing exposing the metal gate structure of the semiconductor device, and forming a first contact to a first portion of the metal gate structure and a second contact to a second portion of the metal gate structure, the first portion and the second portion of the metal gate structure being separated by the cut metal gate plug.

Uniform layouts for SRAM and register file bit cells are described. In an example, an integrated circuit structure includes a six transistor (6T) static random access memory (SRAM) bit cell on a substrate. The 6T SRAM bit cell includes first and second active regions parallel along a first direction of the substrate. First, second, third and fourth gate lines are over the first and second active regions, the first, second, third and fourth gate lines parallel along a second direction of the substrate, the second direction perpendicular to the first direction.

A static random access memory (SRAM) periphery circuit includes a first n-type transistor and a second n-type transistor that are disposed in a first well region of first conductivity type, the first well region occupies a first distance in a row direction equal to a bitcell-pitch of an SRAM array. The SRAM periphery circuit includes a first p-type transistor and a second p-type transistor that are disposed in a second well region of second conductivity type. The second well region occupies a second distance in the row direction equal to the bitcell-pitch of the SRAM array. The second well region is disposed adjacent to the first well region in the row direction.