Abstract: Corner portions of a semiconductor fin are kept on the device while removing a semiconductor fin prior to forming a backside contact. The corner portions of the semiconductor fin protect source/drain regions from etchant during backside processing. The corner portions allow the source/drain features to be formed with a convex profile on the backside. The convex profile increases volume of the source/drain features, thus, improving device performance. The convex profile also increases processing window of backside contact recess formation.

Abstract: A method of independently forming source/drain regions in NMOS regions including nanosheet field-effect transistors (NSFETs), NMOS regions including fin field-effect transistors (FinFETs) PMOS regions including NSFETs, and PMOS regions including FinFETs and semiconductor devices formed by the method are disclosed. In an embodiment, a device includes a semiconductor substrate; a first nanostructure over the semiconductor substrate; a first epitaxial source/drain region adjacent the first nanostructure; a first inner spacer layer adjacent the first epitaxial source/drain region, the first inner spacer layer comprising a first material; a second nanostructure over the semiconductor substrate; a second epitaxial source/drain region adjacent the second nanostructure; and a second inner spacer layer adjacent the second epitaxial source/drain region, the second inner spacer layer comprising a second material different from the first material.

Abstract: A semiconductor device according to the present disclosure includes an active region including a channel region and a source/drain region adjacent the channel region, a vertical stack of channel members over the channel region, a gate structure over and around the vertical stack of channel members, a bottom dielectric feature over the source/drain region, a source/drain feature over the bottom dielectric feature, and a germanium layer disposed between the bottom dielectric feature and the source/drain region.

Abstract: A method of fabricating a device includes providing a fin having a plurality of channel layers and a plurality of multilayer epitaxial layers interposing the plurality of channel layers. The multilayer epitaxial layers include a first epitaxial layer interposed between second and third epitaxial layers. The first epitaxial layer has a first etch rate and the second and third epitaxial layers have a second etch rate greater than the first etch rate. The method further includes laterally etching the first, second, and third epitaxial layers to provide a convex sidewall profile on opposing lateral surfaces of the multilayer epitaxial layers. The method further includes forming an inner spacer between adjacent channel layers. The inner spacer interfaces the convex sidewall profile of the multilayer epitaxial layers along a first inner spacer sidewall surface. The method further includes replacing the multilayer epitaxial layers with a portion of a gate structure.

Abstract: A semiconductor device including a substrate having a NMOS region and a PMOS region; a metal gate extending continuously along a first direction from the NMOS region to the PMOS region on the substrate; a first source/drain region extending along a second direction adjacent to two sides of the metal gate on the NMOS region; a second source/drain region extending along the second direction adjacent to two sides of the metal gate on the PMOS region; a first contact plug landing on the second source/drain region adjacent to one side of the metal gate; a second contact plug landing on the second source/drain region adjacent to another side of the metal gate; and a third contact plug landing directly on a portion of the metal gate on the PMOS region and between the first contact plug and the second contact plug.

Abstract: A semiconductor device according to the present disclosure includes an active region including a channel region and a source/drain region adjacent the channel region, a vertical stack of channel members over the channel region, a gate structure over and around the vertical stack of channel members, a bottom dielectric feature over the source/drain region, a source/drain feature over the bottom dielectric feature, and a germanium layer disposed between the bottom dielectric feature and the source/drain region.

Abstract: A semiconductor device includes a semiconductor substrate having a fin structure, a gate stack across the fin structure, a spacer structure on a sidewall of the gate stack, an epitaxial structure on the semiconductor substrate, and a dielectric structure in the spacer structure. The dielectric structure extends along a lower portion of the spacer structure and across the fin structure.

Abstract: Semiconductor device and the manufacturing method thereof are disclosed. An exemplary method comprises alternately forming first semiconductor layers and second semiconductor layers over a substrate, wherein the first semiconductor layers and the second semiconductor layers include different materials and are stacked up along a direction substantially perpendicular to a top surface of the substrate; forming a dummy gate structure over the first and second semiconductor layers; forming a source/drain (S/D) trench along a sidewall of the dummy gate structure; forming inner spacers between edge portions of the first semiconductor layers, wherein the inner spacers are bended towards the second semiconductor layers; and epitaxially growing a S/D feature in the S/D trench, wherein the S/D feature contacts the first semiconductor layers and includes facets forming a recession away from the inner spacers.

Abstract: A device includes an active region, a gate structure, an epitaxial structure, an epitaxial layer, a metal alloy layer, a contact, and a contact etch stop layer. The gate structure is across the active region. The epitaxial structure is above the active region and adjacent the gate structure. The epitaxial layer is above the epitaxial structure. The metal alloy layer is above the epitaxial layer. The contact is above the metal alloy layer. The contact etch stop layer lines sidewalls of the epitaxial structure. The metal alloy layer is spaced apart from the contact etch stop layer.

Abstract: A semiconductor device according to the present disclosure includes a bottom dielectric feature on a substrate, a plurality of channel members directly over the bottom dielectric feature, a gate structure wrapping around each of the plurality of channel members, two first epitaxial features sandwiching the bottom dielectric feature along a first direction, and two second epitaxial features sandwiching the plurality of channel members along the first direction.

Abstract: A semiconductor device structure is provided. The semiconductor device structure includes a substrate having a base portion and a fin portion over the base portion. The semiconductor device structure includes an epitaxial structure over the fin portion. The semiconductor device structure includes a dielectric fin over the base portion. The semiconductor device structure includes a silicide layer between the dielectric fin and the epitaxial structure. A distance between the silicide layer and the dielectric fin increases toward the base portion.

Abstract: A semiconductor device includes a substrate having a NMOS region and a PMOS region; a gate structure extending along a first direction from the NMOS region to the PMOS region on the substrate; and a first contact plug landing directly on the gate structure closer to the PMOS region from a boundary separating the NMOS region and the PMOS region. Preferably, the semiconductor device further includes a first source/drain region extending along a second direction adjacent to two sides of the gate structure on the NMOS region and a second source/drain region extending along the second direction adjacent to two sides of the gate structure on the PMOS region.

Abstract: Self-aligned gate cutting techniques are disclosed herein that provide dielectric gate isolation fins for isolating gates of multigate devices from one another. An exemplary device includes a first multigate device having first source/drain features and a first metal gate that surrounds a first channel layer and a second multigate device having second source/drain features and a second metal gate that surrounds a second channel layer. A dielectric gate isolation fin separates the first metal gate from the second metal gate. The dielectric gate isolation fin includes a first dielectric layer having a first dielectric constant and a second dielectric layer having a second dielectric constant disposed over the first dielectric layer. The second dielectric constant is greater than the first dielectric constant. The first metal gate and the second metal gate physically contact the first channel layer and the second channel layer, respectively, and the dielectric gate isolation fin.

Abstract: A method includes forming an epitaxy semiconductor layer over a semiconductor substrate, and etching the epitaxy semiconductor layer and the semiconductor substrate to form a semiconductor strip, which includes an upper portion acting as a mandrel, and a lower portion under the mandrel. The upper portion is a remaining portion of the epitaxy semiconductor layer, and the lower portion is a remaining portion of the semiconductor substrate. The method further includes growing a first semiconductor fin starting from a first sidewall of the mandrel, growing a second semiconductor fin starting from a second sidewall of the mandrel. The first sidewall and the second sidewall are opposite sidewalls of the mandrel. A first transistor is formed based on the first semiconductor fin. A second transistor is formed based on the second semiconductor fin.

Abstract: A semiconductor device includes a substrate, a semiconductor layer, a gate structure, source/drain regions, a bottom isolation layer, and a bottom spacer. The semiconductor layer is above the substrate. The gate structure is above the substrate and surrounds the semiconductor layer. The source/drain regions are on opposite sides of the semiconductor layer. The bottom isolation layer is between the substrate and the semiconductor layer. The bottom spacer is on a sidewall of the bottom isolation layer.

Abstract: A semiconductor structure is provided. The semiconductor structure includes nanostructures over a substrate, a gate stack around the nanostructures, a gate spacer layer alongside the gate stack, an inner spacer layer between the gate spacer layer and the nanostructures, a source/drain feature adjoining the nanostructures, a contact plug over the source/drain feature, and a silicon germanium layer along the surface of the source/drain feature and between the contact plug and the inner spacer layer.

Abstract: An electronic device, a fingerprint sensing control method and a fingerprint scanning control method are provided. A sensing region of a display panel is divided into a plurality of fingerprint zones. The electronic device determines at least one target fingerprint zone from the fingerprint zones according to a touched area. The electronic device scans the at least one target fingerprint zone to control the at least one target fingerprint zone for performing fingerprint sensing. The electronic device performs an accelerated scanning operation. The accelerated scanning operation includes: setting a scanning speed corresponding to at least one target scanning group coupled to at least the touched area to a first speed; and setting a scanning speed corresponding to one or more scanning groups other than the at least one target scanning group to a second speed higher than the first speed.

Abstract: A method of independently forming source/drain regions in NMOS regions including nanosheet field-effect transistors (NSFETs), NMOS regions including fin field-effect transistors (FinFETs) PMOS regions including NSFETs, and PMOS regions including FinFETs and semiconductor devices formed by the method are disclosed. In an embodiment, a device includes a semiconductor substrate; a first nanostructure over the semiconductor substrate; a first epitaxial source/drain region adjacent the first nanostructure; a first inner spacer layer adjacent the first epitaxial source/drain region, the first inner spacer layer comprising a first material; a second nanostructure over the semiconductor substrate; a second epitaxial source/drain region adjacent the second nanostructure; and a second inner spacer layer adjacent the second epitaxial source/drain region, the second inner spacer layer comprising a second material different from the first material.

Abstract: A semiconductor structure is received that has a first and second fins. A first epitaxial feature is formed on the first fin and has a first type dopant. A first capping layer is formed over the first epitaxial feature. A second epitaxial feature is formed on the second fin and has a second type dopant different from the first type dopant. A first metal is deposited on the second epitaxial feature and on the first capping layer. A first silicide layer is formed from the first metal and the second epitaxial feature, and a second capping layer is formed from the first metal and the first capping layer. The second capping layer is selectively removed. A second metal is deposited on the first epitaxial feature and over the second epitaxial feature. A second silicide layer is formed from the second metal and the first epitaxial feature.

Abstract: A semiconductor device includes a semiconductor substrate having a fin structure, a gate stack across the fin structure, a spacer structure on a sidewall of the gate stack, an epitaxial structure on the semiconductor substrate, and a dielectric structure in the spacer structure. The dielectric structure extends along a lower portion of the spacer structure and across the fin structure.