A device includes a substrate, and a first semiconductor channel over the substrate. The first semiconductor channel includes a first nanosheet of a first semiconductor material, a second nanosheet of a second semiconductor material in physical contact with a topside surface of the first nanosheet, and a third nanosheet of the second semiconductor material in physical contact with an underside surface of the first nanosheet. The first gate structure is over and laterally surrounding the first semiconductor channel, and in physical contact with the second nanosheet and the third nanosheet.

A device includes a semiconductor substrate and a first gate stack over the semiconductor substrate, the first gate stack being between a first gate spacer and a second gate spacer. The device further includes a second gate stack over the semiconductor substrate between the first gate spacer and the second gate spacer and a dielectric material separating the first gate stack from the second gate stack. The dielectric material is at least partially between the first gate spacer and the second gate spacer, a first width of an upper portion of the dielectric material is greater than a second width of a lower portion of the dielectric material, and a third width of an upper portion of the first gate spacer is less than a fourth width of a lower portion of the first gate spacer.

Techniques and mechanisms for operating transistors that are in a stacked configuration. In an embodiment, an integrated circuit (IC) device includes transistors arranged along a line of direction which is orthogonal to a surface of a semiconductor substrate. A first epitaxial structure and a second epitaxial structure are coupled, respectively, to a first channel structure of a first transistor and a second channel structure of a second transistor. The first epitaxial structure and the second epitaxial structure are at different respective levels relative to the surface of the semiconductor substrate. A dielectric material is disposed between the first epitaxial structure and the second epitaxial structure to facilitate electrical insulation of the channels from each other. In another embodiment, the stacked transistors are coupled to provide a complementary metal-oxide-semiconductor (CMOS) inverter circuit.

A semiconductor device is provided in the disclosure, including a substrate, multiple parallel fins protruding from the substrate and isolated by trenches, and a device insulating layer on the trenches between two fins, wherein the trench is provided with a central first trench and two second trenches at both sides of the first trench, and a depth of the first trench is deeper than a depth of the second trench, and the device insulating layer is provided with a top plane, a first trench and a second trench, and the fins protrude from the top plane, and the bottom surface of the second trench is lower than the bottom surface of the first trench.

Techniques are disclosed for non-planar transistors having varying channel widths (Wsi). In some instances, the resulting structure has a fin (or nanowires, nanoribbons, or nanosheets) comprising a first channel region and a second channel region, with a source or drain region between the first channel region and the second channel region. The widths of the respective channel regions are independent of each other, e.g., a first width of the first channel region is different from a second width of the second channel region. The variation in width of a given fin structure may vary in a symmetric fashion or an asymmetric fashion. In an embodiment, a spacer-based forming approach is utilized that allows for abrupt changes in width along a given fin. Sub-resolution fin dimensions are achievable as well.

Methods and apparatus to form silicon-based transistors on group III-nitride materials using aspect ratio trapping are disclosed. An example integrated circuit includes a group III-nitride substrate and a fin of silicon formed on the group III-nitride substrate. The integrated circuit further includes a first transistor formed on the fin of silicon and a second transistor formed on the group III-nitride substrate.

Embodiments of present invention provide a semiconductor device. The semiconductor device includes a silicon (Si) substrate containing a set of short channel field-effect-transistors (FETs); a germanium (Ge) layer on top of the Si substrate containing a set of long channel p-type FETs (PFETs); and an oxide semiconductor layer on top of the Ge layer containing a set of long channel n-type FETs (NFETs), wherein the set of short channel FETs, long channel PFETs, and long channel NFETs are interconnected through a set of far-back-end-of-line (FBEOL) layers.

An example includes a semiconductor structure including a semiconductor layer, front-side logic devices arranged in a front-side of the semiconductor layer, four epitaxial layers on a back-side of the semiconductor layer, where the four epitaxial layers include a first epitaxial layer of a first conductivity type, a second epitaxial layer of a second conductivity type, a third epitaxial layer of the second conductivity type, and a fourth epitaxial layer of the first conductivity type, a plurality of back-side contacts exposed at a back-side surface of the fourth epitaxial layer, where the plurality of back-side contacts include a set of first terminal contacts extending into and contacting the fourth epitaxial layer, a set of second terminal contacts extending into and contacting the second epitaxial layer, a set of first gate contacts extending into the third epitaxial layer, and a set of second gate contacts extending into the first epitaxial layer.

A method for processing an integrated circuit includes forming N-type and P-type gate all around transistors and core gate all around transistors. The method deposits a metal gate layer for the P-type transistors. The method forms a passivation layer in-situ with the metal gate layer of the P-type transistor.

Provided is a semiconductor structure with shared gated devices. The semiconductor structure comprises a substrate and a bottom dielectric isolation (BDI) layer on top of the substrate. The structure further comprises a pFET region that includes a p-doped Source-Drain epitaxy material and a first nanowire matrix above the BDI layer. The structure further comprises an nFET region that includes a n-doped Source-Drain epitaxy material and a second nanowire matrix above the BDI layer. The structure further comprises a conductive gate material on top of a portion of the first nanowire matrix and the second nanowire matrix. The structure further comprises a vertical dielectric pillar separating the pFET region and the nFET region. The vertical dielectric pillar extends downward through the BDI layer into the substrate. The vertical dielectric pillar further extends upward through the conductive gate material to a dielectric located above the gate region.