An integrated circuit includes a nanosheet transistor having a plurality of stacked channels, a gate electrode surrounding the stacked channels, a source/drain region, and a source/drain contact. The integrated circuit includes a first dielectric layer between the gate metal and the source/drain contact, a second dielectric layer on the first dielectric layer, and a cap metal on the first gate metal and on a hybrid fin structure. The second dielectric layer is on the hybrid fin structure between the cap metal and the source/drain contact.

A semiconductor device includes a first active region, a second active region spaced apart from the first active region, a plurality of first channel layers disposed on the first active region, and a second channel layer disposed on the second active region. The semiconductor device further includes a first gate structure intersecting the first active region and the first channel layers, a second gate structure intersecting the second active region and the second channel layer, a first source/drain region disposed on the first active region and contacting the plurality of first channel layers, and a second source/drain region and contacting the second channel layer. The plurality of first channel layers includes a first uppermost channel layer and first lower channel layers disposed below the first uppermost channel layer, and the first uppermost channel layer includes a material that is different from a material included in the first lower channel layers.

A manufacturing method of a semiconductor device includes forming a stack of first semiconductor layers and second semiconductor layers alternatively formed on top of one another, where a topmost layer of the stack is one of the second semiconductor layers; forming a patterned mask layer on the topmost layer of the stack; forming a trench in the stack based on the patterned mask layer to form a fin structure; forming a cladding layer extending along sidewalls of the fin structure; and removing the patterned mask layer and a portion of the cladding layer by performing a two-step etching process, where the portion of the cladding layer is removed to form cladding spacers having a concave top surface with a recess depth increasing from the sidewalls of the fin structure.

Self-aligned gate endcap (SAGE) architectures with gate-all-around devices, and methods of fabricating self-aligned gate endcap (SAGE) architectures with gate-all-around devices, are described. In an example, an integrated circuit structure includes a semiconductor fin above a substrate and having a length in a first direction. A nanowire is over the semiconductor fin. A gate structure is over the nanowire and the semiconductor fin, the gate structure having a first end opposite a second end in a second direction, orthogonal to the first direction. A pair of gate endcap isolation structures is included, where a first of the pair of gate endcap isolation structures is spaced equally from a first side of the semiconductor fin as a second of the pair of gate endcap isolation structures is spaced from a second side of the semiconductor fin.

A semiconductor device fabricated by forming FET fins from a layered semiconductor structure. The layered semiconductor structure incudes a sacrificial layer. Further by forming dummy gate structures on the FET fins, recessing the FET fins between dummy gate structures, growing source-drain regions between FET fins and the sacrificial layer, replacing active region dummy gate structures with high-k metal gates structures, and replacing the sacrificial layer with a dielectric isolation material, wherein the dielectric isolation material extends across the active region.

An apparatus including a device including a channel material having a first lattice structure on a well of a well material having a matched lattice structure in a buffer material having a second lattice structure that is different than the first lattice structure. A method including forming a trench in a buffer material; forming an n-type well material in the trench, the n-type well material having a lattice structure that is different than a lattice structure of the buffer material; and forming an n-type transistor. A system including a computer including a processor including complimentary metal oxide semiconductor circuitry including an n-type transistor including a channel material, the channel material having a first lattice structure on a well disposed in a buffer material having a second lattice structure that is different than the first lattice structure, the n-type transistor coupled to a p-type transistor.

A method of manufacturing a semiconductor device includes forming a first trench in a semiconductor substrate from a first side, forming a semiconductor layer adjoining the semiconductor substrate at the first side, the semiconductor layer capping the first trench at the first side, and forming a contact at a second side of the semiconductor substrate opposite to the first side.

By forming a trench isolation structure after providing a high-k dielectric layer stack, direct contact of oxygen-containing insulating material of a top surface of the trench isolation structure with the high-k dielectric material in shared polylines may be avoided. This technique is self-aligned, thereby enabling further device scaling without requiring very tight lithography tolerances. After forming the trench isolation structure, the desired electrical connection across the trench isolation structure may be re-established by providing a further conductive material.

A method includes forming a first semiconductor stack using an epitaxial growth process, the first semiconductor stack comprising a first plurality of semiconductor layers alternating with a second plurality of semiconductor layers, the first plurality of semiconductor layers comprising a first semiconductor material and the second plurality of semiconductor layers comprising a second semiconductor material that is different than the first semiconductor material. The method further includes patterning the first semiconductor stack to form a set of semiconductor stack features, forming isolation features between the semiconductor stack features, removing at least one of the semiconductor stack features, thereby forming at least one trench, and forming, within the trench, a second semiconductor stack using an epitaxial growth process, the second semiconductor stack having different characteristics than the first semiconductor stack.

The present invention provides a switching device (100) for power conversion in which a first gate electrode (6), a p-type channel layer (2) having an n-type emitter region (3), a second gate electrode (13), and a p-type floating layer (15) are repeatedly arranged in order on the surface side of an n.sup.type semiconductor substrate (1). An interval a between the two gates (6, 13) that sandwich the p-type channel layer (2) is configured to be smaller than an interval b between the two gates (13, 6) that sandwich the p-type floating layer (15). The first gate electrode (6) and the second gate electrode (13) are both supplied with drive signals having a time difference in drive timing.