Abstract: A method of fabricating a semiconductor device is described. A substrate is provided. A first semiconductor region of a first semiconductor material is formed over the substrate and adjacent a second semiconductor region of a second semiconductor material. The first and second semiconductor regions are crystalline. An etchant is selective to etch the first semiconductor region over the second semiconductor region. The entire first semiconductor region is implanted to form an amorphized semiconductor region. The amorphized semiconductor region is etched with the etchant using the second semiconductor region as a mask to remove the amorphized semiconductor region without removing the second semiconductor region.

Abstract: A method for making a middle-of-line interconnect structure in a semiconductor device includes forming, near a surface of a first interconnect structure comprised of a first metal, a region of varied composition including the first metal and a second element. The method further includes forming a recess within the region of varied composition. The recess laterally extends a first distance along the surface and vertically extends a second distance below the first surface. The method further includes filling the recess with a second metal to form a second interconnect structure that contacts the first interconnect structure.

Abstract: A semiconductor device includes a gate electrode over a channel region of a semiconductor fin, first spacers over the semiconductor fin, and second spacers over the semiconductor fin. A lower portion of the gate electrode is between the first spacers. An upper portion of the gate electrode is above the first spacers. The second spacers are adjacent the first spacers opposite the gate electrode. The upper portion of the gate electrode is between the second spacers.

Abstract: A method includes depositing a first work function layer over a gate dielectric layer, forming a first hard mask layer over the first work function layer, forming a photoresist mask over the first hard mask layer, where forming the photoresist mask includes depositing a bottom anti-reflective coating (BARC) layer over the first hard mask layer, etching a portion of the BARC layer, etching a portion of the first hard mask layer using the BARC layer as a mask, etching a portion of the first work function layer to expose a portion of the gate dielectric layer through the first hard mask layer and the first work function layer, removing the first hard mask layer, and depositing a second work function layer over the first work function layer and over the portion of the gate dielectric layer.

Abstract: A method includes forming isolation regions extending into a semiconductor substrate. A semiconductor strip is between the isolation regions. The method further includes recessing the isolation regions so that a top portion of the semiconductor strip protrudes higher than top surfaces of the isolation regions to form a semiconductor fin, measuring a fin width of the semiconductor fin, generating an etch recipe based on the fin width, and performing a thinning process on the semiconductor fin using the etching recipe.

Abstract: A method for making a middle-of-line interconnect structure in a semiconductor device includes forming, near a surface of a first interconnect structure comprised of a first metal, a region of varied composition including the first metal and a second element. The method further includes forming a recess within the region of varied composition. The recess laterally extends a first distance along the surface and vertically extends a second distance below the first surface. The method further includes filling the recess with a second metal to form a second interconnect structure that contacts the first interconnect structure.

Abstract: The present disclosure describes structure and method of a fin field-effect transistor (finFET) device. The finFET device includes: a substrate, a fin over the substrate, and a gate structure over the fin. The gate structure includes a work-function metal (WFM) layer over an inner sidewall of the gate structure. A topmost surface of the WFM layer is lower than a top surface of the gate structure. The gate structure also includes a filler gate metal layer over the topmost surface of the WFM layer. A top surface of the filler gate metal layer is substantially co-planar with the top surface of the gate structure. The gate structure further includes a self-assembled monolayer (SAM) between the filler gate metal layer and the WFM layer.

Abstract: A method for cleaning a semiconductor wafer is provided. The method includes placing a semiconductor wafer over a supporter arranged around a central axis of a spin base. The method further includes securing the semiconductor wafer using a clamping member positioned on the supporter. The movement of the semiconductor wafer during the placement of the semiconductor wafer over the supporter is guided by a guiding member located over the clamping member. The method also includes spinning the semiconductor wafer by rotating the spin base about the central axis. In addition, the method includes dispensing a processing liquid over the semiconductor wafer.

Abstract: A method for selectively removing a tungsten-including layer includes: forming a tungsten-including layer which has a first portion and a second portion; performing a treatment on a surface region of the first portion of the tungsten-including layer so as to convert tungsten in the surface region into tungsten oxide; and partially removing the tungsten-including layer using an etchant which has a higher etching selectivity to tungsten than tungsten oxide such that the second portion of the tungsten-including layer is fully removed, and the first portion of the tungsten-including layer, having the tungsten oxide in the surface region, is at least partially retained.

Abstract: A semiconductor device is disclosed. The semiconductor device includes a semiconductor fin. The semiconductor device includes a gate spacer over the semiconductor fin. A lower portion of the gate spacer surrounds a first region and an upper portion of the gate spacer surrounds a second region. The semiconductor device includes a gate dielectric within the first region. The semiconductor device includes a metal gate within the first region. The semiconductor device includes a dielectric protection layer, in contact with the gate dielectric layer, that includes a first portion within the second region and a second portion lining a top surface of the metal gate.

Abstract: A method for processing a substrate is provided. The method includes the following operations: placing a substrate over a first injector in a substrate processing apparatus, the substrate having a front surface and a back surface opposite to the front surface, and the front surface having a plurality of concentric regions; adjusting a temperature of each of the plurality of concentric regions by controlling at least one of a flow rate and a temperature associated with a fluid dispensing from the first injector; and rotating the substrate by a spin base disposed below the substrate, the substrate is rotated with respect to a center axis perpendicular to the front surface thereof when adjusting the temperature. The spin base includes a ring opening for rotating relative to the first injector, and the first injector is displaced from a projection of a center of the substrate from a top view perspective.

Abstract: The present disclosure describes structure and method of a fin field-effect transistor (finFET) device. The finFET device includes: a substrate, a fin over the substrate, and a gate structure over the fin. The gate structure includes a work-function metal (WFM) layer over an inner sidewall of the gate structure. A topmost surface of the WFM layer is lower than a top surface of the gate structure. The gate structure also includes a filler gate metal layer over the topmost surface of the WFM layer. A top surface of the filler gate metal layer is substantially co-planar with the top surface of the gate structure. The gate structure further includes a self-assembled monolayer (SAM) between the filler gate metal layer and the WFM layer.

Abstract: A method for manufacturing a semiconductor device includes forming a metal-including layer over a semiconductor substrate; forming a hydrophobic polymer layer over the metal-including layer; and forming an amphiphilic polymer layer between the metal-including layer and the hydrophobic polymer layer so as to enhance a bonding force therebetween.

Abstract: A semiconductor device includes a semiconductor fin. The semiconductor device includes a metal gate disposed over the semiconductor fin. The semiconductor device includes a gate dielectric layer disposed between the semiconductor fin and the metal gate. The semiconductor device includes first spacers sandwiching the metal gate. The first spacers have a first top surface and the gate dielectric layer has a second top surface, and the first top surface and a first portion of the second top surface are coplanar with each other. The semiconductor device includes second spacers further sandwiching the first spacers. The second spacers have a third top surface above the first top surface and the second top surface. The semiconductor device includes a gate electrode disposed over the metal gate.

Abstract: A method of forming a semiconductor device includes forming an epitaxial source/drain (S/D) structure adjacent to a gate structure; forming a dielectric structure over the gate and epitaxial S/D structures; forming a trench in the dielectric structure to accessibly expose a portion of the epitaxial S/D structure; forming a contact feature from the portion of the epitaxial S/D structure within the trench; and forming a S/D contact in the trench to be in contact with the contact feature overlying the epitaxial S/D structure. Forming the contact feature includes forming a metallic layer in the trench; performing a thermal process on the metallic layer to form the contact feature, where after the thermal process, metallic residues remain on a sidewall of a spacer of the dielectric structure in the trench; and removing the metallic residues by using a wet etching process, wherein the spacer of the dielectric structure remains substantially intact.

Abstract: A method includes depositing a first work function layer over a first and second gate trench. The method includes depositing a second work function layer over the first work function layer. The method includes etching the second work function layer in the first gate trench while covering the second work function layer in the second gate trench, causing the first work function layer in the first gate trench to contain metal dopants that are left from the second work function layer etched in the first gate trench. The method includes forming a first active gate structure and second active gate structure, which include the first work function layer and the metal dopants left from the second work function layer in the first gate trench, and the first work function layer and no metal dopants left behind from the second work function layer, respectively.

Abstract: A method of forming a semiconductor device includes: forming a semiconductor structure having source/drain regions, a fin disposed between the source/drain regions, and a dummy gate disposed on the fin and surrounded by a spacer; removing the dummy gate to form a gate trench which is defined by a trench-defining wall; forming a gate dielectric layer on the trench-defining wall; forming a work function structure on the gate dielectric layer; forming a resist layer to fill the gate trench; removing a top portion of the resist layer; removing the work function structure exposed from the resist layer using a wet chemical etchant; removing the resist layer; and forming a conductive gate in the gate trench.

Abstract: A wet etching chemistry to selectively remove a polymer residue on an opening embedded in a low-k dielectric layer and an underlying stop layer in a process of forming an interconnect structure is provided. The wet etching chemistry includes: two type of organic solvents, wherein a concentration of the two type of organic solvents is greater than or equal to 70%; an Alkali source amine, at least comprising a tertiary amine; an inhibitor; and water. In some embodiment, the wet etching chemistry is free of a peroxide to avoid damage to the WdC hard mask.

Abstract: A semiconductor device structure and a manufacturing method thereof are provided. The structure includes a substrate having a first region and a second region, first and second semiconductor channel sheets, first and second gate structure and source and drain regions. The first and second semiconductor channel sheets are disposed over the substrate and respectively in the first region and the second region. The first semiconductor channel sheets have a first channel width shorter than a second channel width of the second semiconductor channel sheets. The first and second gate structures are disposed over and laterally surrounding the first and second semiconductor channel sheets respectively. The first gate structure includes a first gate dielectric layer and a first metallic layer. The second gate structure includes a second gate dielectric layer and a second metallic layer. The source and drain regions are located beside the first and second semiconductor channel sheets.

Abstract: A semiconductor device is disclosed. The semiconductor device includes a semiconductor fin. The semiconductor device includes a gate spacer over the semiconductor fin. A lower portion of the gate spacer surrounds a first region and an upper portion of the gate spacer surrounds a second region. The semiconductor device includes a gate dielectric within the first region. The semiconductor device includes a metal gate within the first region. The semiconductor device includes a dielectric protection layer, in contact with the gate dielectric layer, that includes a first portion within the second region and a second portion lining a top surface of the metal gate.