A first TS is coupled to first S/D over first fin, second TS coupled to second S/D over first fin, third TS coupled to third S/D over second fin, fourth TS coupled to fourth S/D over second fin, gate metal over first and second fins, and gate cap over gate metal. First TS cap is on first TS, second TS cap on second TS, third TS cap on third TS, and fourth TS cap on fourth TS. ILD is formed on top of gate cap and first through fourth TS caps. First opening is through ILD and second TS cap such that part of gate metal is exposed, after removing part of gate cap. Second opening is through ILD to expose another part of gate metal. Combined gate metal contact and local metal connection is formed in first opening and individual gate metal contact is formed in second opening.

A technique relates to a semiconductor device. A first trench silicide (TS) is coupled to a first source or drain (S/D). A second TS is coupled to a second S/D, and a gate metal is separated from the first and second TS. A trench is formed above and on sides of the gate metal. A local connection metal is formed in the trench such that the gate metal is coupled to the first TS and the second TS. A local connection cap is formed on top of the local connection metal.

Semiconductor devices and methods are provided to fabricate field effect transistor (FET) devices having local wiring between the stacked devices. For example, a semiconductor device includes a first FET device on a semiconductor substrate, the FET device comprising a first source/drain layer, and a first gate structure comprising a gate dielectric layer and a metal gate layer. The semiconductor device further includes a second FET device comprising a second source/drain layer, and a second gate structure comprising a gate dielectric layer and a metal gate layer; wherein the first and second FET devices are in a stacked configuration. The semiconductor device further includes one or more conductive vias in communication with either the first gate structure of the first FET device or the second gate structure of the second FET device.

A semiconductor structure includes a substrate and a CMOS structure. The CMOS structure includes a PMOS structure and a NMOS structure. The PMOS structure includes two first source/drain regions disposed in the substrate, a first gate dielectric disposed partially in the substrate between the first source/drain regions, and a fully silicided gate electrode disposed on the first gate dielectric. The NMOS structure includes two second source/drain regions disposed in the substrate, a second gate dielectric disposed partially in the substrate between the second source/drain regions, and a non-silicided conductive gate electrode disposed on the second gate dielectric.

A semiconductor structure is provided that includes a pFET gate-all-around nanosheet structure and an nFET gate-all-around nanosheet structure integrated together on the same substrate. The pFET gate-all-around nanosheet structure contains a nickel monosilicide gate electrode layer that does not introduce strain into each suspended semiconductor channel material nanosheet of a first vertical stack of suspended semiconductor channel material nanosheets. The nFET gate-all-around nanosheet structure contains a Ni.sub.3Si gate electrode layer that introduces strain into each suspended semiconductor channel material nanosheet of a second vertical stack of suspended semiconductor channel material nanosheets.

Some embodiments include an integrated assembly having a first gate operatively adjacent a channel region, a first source/drain region on a first side of the channel region, and a second source/drain region on an opposing second side of the channel region. The first source/drain region is spaced from the channel region by an intervening region. The first and second source/drain regions are gatedly coupled to one another through the channel region. A second gate is adjacent a segment of the intervening region and is spaced from the first gate by an insulative region. A lightly-doped region extends across the intervening region and is under at least a portion of the first source/drain region. Some embodiments include methods of forming integrated assemblies.

A microelectronic device includes a substrate a platinum-containing layer over the substrate. The platinum-containing layer includes a first segment and a second segment adjacent to the first segment, and has a first surface and a second surface opposite the first surface closer to the substrate than the first surface. A first spacing between the first segment and the second segment at the first surface is greater than a second spacing between the first segment and the second segment at the second surface. A width of the first segment along the first surface is less than twice a thickness of the first segment, and the second spacing is less than twice the thickness of the first segment.

Some embodiments relate to an integrated circuit including a semiconductor substrate including a multi-voltage device region. A first pair of source/drain regions are spaced apart from one another by a first channel region. A dielectric layer is disposed over the first channel region. A barrier layer is disposed over the dielectric layer. A fully silicided gate is disposed over the first channel region and is vertically separated from the semiconductor substrate by a work function tuning layer. The work function tuning layer separates the fully silicided gate from the barrier layer.

An electrode structure is disclosed. The electrode structure includes a first polysilicon layer doped with resistance adjustment impurities; a second polysilicon layer for adjusting grains, formed in the first polysilicon layer and doped with grain adjustment impurities; an ohmic metal layer formed on the first and second polysilicon layers; a barrier metal layer formed on the ohmic metal layer; and a metal layer formed on the barrier metal layer.

A semiconductor structure includes a substrate and a CMOS structure. The CMOS structure includes a PMOS structure and a NMOS structure. The PMOS structure includes two first source/drain regions disposed in the substrate, a first gate dielectric disposed partially in the substrate between the first source/drain regions, and a fully silicided gate electrode disposed on the first gate dielectric. The NMOS structure includes two second source/drain regions disposed in the substrate, a second gate dielectric disposed partially in the substrate between the second source/drain regions, and a non-silicided conductive gate electrode disposed on the second gate dielectric.