A semiconductor structure includes a first field effect transistor including a first gate spacer having first laterally-straight bottom edges that coincide with top edges of first laterally-straight sidewalls of the first gate dielectric. The semiconductor structure further includes a second field effect transistor including a second gate dielectric that includes at least one discrete gate-dielectric opening that overlies a respective second active region, and a second gate spacer including a contoured portion that overlies and laterally surrounds a second gate electrode, and at least one horizontally-extending portion that overlies the second active region and including at least one discrete gate-spacer openings. The second field effect transistor may have a symmetric or non-symmetric configuration.

Provided is a semiconductor device which includes: a 1.sup.st source/drain region connected to a 1.sup.st channel structure which is controlled by a 1.sup.st gate structure; a 2.sup.nd source/drain region, above the 1.sup.st source/drain region, connected to a 2.sup.nd channel structure which is controlled by a 2.sup.nd gate structure; and a middle isolation structure between the 1.sup.st gate structure and the 2.sup.nd gate structure, wherein the middle isolation structure comprises two or more vertically-stacked semiconductor layers.

A semiconductor fabrication method includes: forming an epitaxial stack including at least one sacrificial epitaxial layer and at least one channel epitaxial layer; forming a plurality of fins in the epitaxial stack; performing tuning operations to prevent a width of the sacrificial epitaxial layer expanding beyond a width of the channel epitaxial layer during operations to form isolation features; forming the isolation features between the plurality of fins, wherein the width of the sacrificial epitaxial layer does not expand beyond the width of the channel epitaxial layer; forming a sacrificial gate stack; forming gate sidewall spacers on sidewalls of the sacrificial gate stack; forming inner spacers around the sacrificial epitaxial layer and the channel epitaxial layer; forming source/drain features; removing the sacrificial gate stack and sacrificial epitaxial layer; and forming a replacement metal gate, wherein the metal gate is shielded from the source/drain features.

A method includes: forming a stack of semiconductor nanostructures on a semiconductor fin; forming a source/drain opening adjacent the stack; forming a bottom dielectric layer on the semiconductor fin; forming a source/drain region in the source/drain opening, a void being present between the source/drain region and the bottom dielectric layer; forming a dielectric layer on the source/drain region; forming a hardened portion of the dielectric layer by treating the dielectric layer, the hardened portion having higher etch selectivity than other portions of the dielectric layer; removing the other portions of the dielectric layer, exposing the void; forming a source/drain contact opening that extends to and connects with the void, the source/drain contact opening exposing sidewalls of the source/drain region; forming a liner layer on exposed surfaces of the source/drain region; and forming a conductive core layer on the liner layer, the conductive core layer being in contact with the liner layer on a top surface, sidewalls and a bottom surface of the source/drain region.

A semiconductor device includes a first active pattern extending in a first direction, a second active pattern on the first active pattern and extending in the first direction, a gate structure on the first active pattern and the second active pattern and extending in a second direction intersecting the first direction, a first source/drain region on side faces of the gate structure and connected to the first active pattern, a second source/drain region on the side faces of the gate structure and connected to the second active pattern, and an intermediate connecting layer which includes a first intermediate conductive pattern between the first active pattern and the second active pattern, and a second intermediate conductive pattern connected to the first intermediate conductive pattern between the first source/drain region and the second source/drain region.

A semiconductor device including a semiconductor substrate. A first transistor and a second transistor are formed on the semiconductor substrate. Each transistor comprises a source, a drain, and a gate. A CA layer forms a local interconnect layer electrically connected to one of the source and the drain of the first transistor. A CB layer forms a local interconnect layer electrically connected to the gate of one of the first transistor and the second transistor. An end of the CB layer is disposed at a center of the CA layer

A non-volatile memory cell includes a p-channel non-volatile transistor having a source and a drain defining a channel and a gate overlying the channel and an n-channel non-volatile transistor having a source and a drain defining a channel and a gate overlying the channel. In at least one of the p-channel non-volatile transistor and the n-channel non-volatile transistor, a lightly-doped drain region extends from the drain into the channel.

Techniques are disclosed for improved integration of germanium (Ge)-rich p-MOS source/drain contacts to, for example, reduce contact resistance. The techniques include depositing the p-type Ge-rich layer directly on a silicon (Si) surface in the contact trench location, because Si surfaces are favorable for deposition of high quality conductive Ge-rich materials. In one example method, the Ge-rich layer is deposited on a surface of the Si substrate in the source/drain contact trench locations, after removing a sacrificial silicon germanium (SiGe) layer previously deposited in the source/drain locations. In another example method, the Ge-rich layer is deposited on a Si cladding layer in the contact trench locations, where the Si cladding layer is deposited on a functional p-type SiGe layer. In some cases, the Ge-rich layer comprises at least 50% Ge (and may contain tin (Sn) and/or Si) and is boron (B) doped at levels above 1E20 cm.sup.3.

A method includes selectively degrading a current capacity of a first finned-field-effect-transistor (finFET) relative to a second finFET by forming a material on a fin of the first finFET to increase a current resistance of the first finFET. The second finFET is electrically connected to the first finFET in a circuit such that a current flow through the second finFET is a multiple of a current flow through the first finFET.

Present disclosure provides a FinFET structure, including a plurality of fins, a gate, and a first dopant layer. The gate is disposed substantially orthogonal over the plurality of fins, covering a portion of a top surface and a portion of sidewalls of the plurality of fins. The first dopant layer covers the top surface and the sidewalls of a junction portion of a first fin, configured to provide dopants of a first conductive type to the junction portion of the first fin. The junction portion is adjacent to the gate.