Abstract: A method includes etching a first portion and a second portion of a dummy gate stack to form a first opening and a second opening, respectively, and depositing a silicon nitride layer to fill the first opening and the second opening. The deposition of the silicon nitride layer comprises a first process selected from treating the silicon nitride layer using hydrogen radicals, implanting the silicon nitride layer, and combinations thereof. The method further includes etching a third portion of the dummy gate stack to form a trench, etching a semiconductor fin underlying the third portion to extend the trench down into a bulk portion of a semiconductor substrate underlying the dummy gate stack, and depositing a second silicon nitride layer into the trench.

Abstract: A method includes forming a semiconductor fin protruding higher than top surfaces of isolation regions. The isolation regions extend into a semiconductor substrate. A portion of the semiconductor fin is etched to form a trench, which extends lower than bottom surfaces of the isolation regions, and extends into the semiconductor substrate. The method further includes filling the trench with a first dielectric material to form a first fin isolation region, recessing the first fin isolation region to form a first recess, and filling the first recess with a second dielectric material. The first dielectric material and the second dielectric material in combination form a second fin isolation region.

Abstract: A semiconductor device includes a plurality of semiconductor fins, at least one gate stack, a refill isolation, and an air gap. Each of the semiconductor fins extends in an X direction. Two adjacent ones of the semiconductor fins are spaced apart from each other in a Y direction transverse to the X direction. The at least one gate stack has two stack sections spaced apart from each other in the Y direction. The stack sections are disposed over two adjacent ones of the semiconductor fins, respectively. The refill isolation and the air gap are disposed between the stack sections.

Abstract: A layer of carbon (e.g., graphite or graphene) at a metal interface (e.g., between an MEOL interconnect and a gate contact or a source or drain region contact, between an MEOL contact plug and a BEOL metallization layer, and/or between BEOL conductive structures) is used to reduce contact resistance at the metal interface, which increases electrical performance of an electronic device. Additionally, in some implementations, the layer of carbon may help prevent heat transfer from a second metal to a first metal when the second metal is deposited over the first metal. This results in more symmetric deposition of the second metal, which reduces surface roughness and contact resistance at the metal interface. As an alternative, in some implementations, the layer of carbon is etched before deposition of the second metal in order to reduce contact resistance at the metal interface.

Abstract: A method of forming a semiconductor device includes forming a mask layer over a substrate and forming an opening in the mask layer. A gap-filling material is deposited in the opening. A plasma treatment is performed on the gap-filling material. The height of the gap-filling material is reduced. The mask layer is removed. The substrate is patterned using the gap-filling material as a mask.

Abstract: A method includes forming a transistor over a front side of a substrate; forming a front-side interconnect structure over the transistor, the front-side interconnect structure comprising layers of conductive lines, and conductive vias interconnecting the layers of conductive lines; forming a first bonding layer over the front-side interconnect structure; forming a second bonding layer over a carrier substrate; bonding the front-side interconnect structure to the carrier substrate by pressing the first bonding layer against the second bonding layer; and forming a backside interconnect structure over a backside of the substrate after bonding the front-side interconnect structure to the carrier substrate.

Abstract: A method includes placing a wafer into a process chamber, and depositing a silicon nitride layer on a base layer of the wafer. The process of depositing the silicon nitride layer includes introducing a silicon-containing precursor into the process chamber, purging the silicon-containing precursor from the process chamber, introducing hydrogen radicals into the process chamber, purging the hydrogen radicals from the process chamber; introducing a nitrogen-containing precursor into the process chamber, and purging the nitrogen-containing precursor from the process chamber.

Abstract: A method includes forming a dielectric layer over a substrate; forming a patterned amorphous silicon layer over a dielectric layer; depositing a first spacer layer over the patterned amorphous silicon layer; depositing a second spacer layer over the first spacer layer; forming a photoresist having an opening over the substrate; depositing a hard mask layer in the opening of the photoresist; after depositing the hard mask layer in the opening of the photoresist, removing the photoresist; and performing an etching process to etch the dielectric layer by using the patterned amorphous silicon layer, the first spacer layer, the second spacer layer, and the hard mask layer as an etch mask, in which the etching process etches the second spacer layer at a slower etch rate than etching the first spacer layer.

Abstract: A method includes depositing a dielectric layer, depositing a plurality of mandrel strips over the dielectric layer, and forming a plurality of spacers on sidewalls of the plurality of mandrel strips to form a plurality of mask groups. Each of the plurality of mandrel strips and two of the plurality of spacers form a mask group in the plurality of mask groups. The method further includes forming a mask strip connecting two neighboring mask groups in the plurality of mask groups, using the plurality of mask groups and the mask strip collectively as an etching mask to etch the dielectric layer and to form trenches in the dielectric layer, and filling a conductive material into the trenches to form a plurality of conductive features.

Abstract: In an embodiment, a method of manufacturing a semiconductor device includes preparing a deposition processing chamber by flowing first precursors to form a dielectric coat along an inner sidewall of the deposition processing chamber and flowing a second precursor to form a hydrophobic layer over the dielectric coat. In addition one or more deposition cycles are performed. Next, the second precursor is flowed again to repair the hydrophobic layer.

Abstract: A semiconductor structure including a substrate, a first dielectric layer, a first conductive feature, an etch stop layer, a second dielectric layer and a second conductive feature is provided. The first dielectric layer is disposed over the substrate. The first conductive feature is disposed in the first dielectric layer. The etch stop layer is disposed over the first dielectric layer and the first conductive feature, wherein the etch stop layer comprises a metal-containing layer and a silicon-containing layer, the metal-containing layer is located between the first dielectric layer and the silicon-containing layer, the metal-containing layer comprises a nitride-containing region and an oxide-containing region, and the nitride-containing region contacts the first conductive feature. The second dielectric layer is disposed over the etch stop layer. The second conductive feature penetrates the second dielectric layer and electrically connects with the first conductive feature.

Abstract: A method includes forming a first and a second dummy gate stack crossing over a semiconductor region, forming an ILD to embed the first and the second dummy gate stacks therein, replacing the first and the second dummy gate stacks with a first and a second replacement gate stack, respectively, performing a first etching process to form a first opening. A portion of the first replacement gate stack and a portion of the second replacement gate stack are removed. The method further includes filling the first opening to form a dielectric isolation region, performing a second etching process to form a second opening, with the ILD being etched, and the dielectric isolation region being exposed to the second opening, forming a contact spacer in the second opening, and filling a contact plug in the second opening. The contact plug is between opposite portions of the contact spacer.

Abstract: A method includes forming a semiconductor fin protruding higher than top surfaces of isolation regions. The isolation regions extend into a semiconductor substrate. A portion of the semiconductor fin is etched to form a trench, which extends lower than bottom surfaces of the isolation regions, and extends into the semiconductor substrate. The method further includes filling the trench with a first dielectric material to form a first fin isolation region, recessing the first fin isolation region to form a first recess, and filling the first recess with a second dielectric material. The first dielectric material and the second dielectric material in combination form a second fin isolation region.

Abstract: An integrated circuit structure includes a gate stack over a semiconductor substrate, and a silicon germanium region extending into the semiconductor substrate and adjacent to the gate stack. The silicon germanium region has a top surface, with a center portion of the top surface recessed from edge portions of the top surface to form a recess. The edge portions are on opposite sides of the center portion.

Abstract: An interconnect structure includes an interconnect structure includes an etching stop layer, a dielectric layer and an insert layer and a conductive line. The insert layer is located between the etching stop layer and the dielectric layer. The conductive line extends through the dielectric layer, the insert layer, and the etching stop layer. A material of the insert layer is different from the dielectric layer and the etching stop layer.

Abstract: An integrated circuit structure includes a gate stack over a semiconductor substrate, and an opening extending into the semiconductor substrate, wherein the opening is adjacent to the gate stack. A first silicon germanium region is disposed in the opening, wherein the first silicon germanium region has a first germanium percentage. A second silicon germanium region is over the first silicon germanium region. The second silicon germanium region comprises a portion in the opening. The second silicon germanium region has a second germanium percentage greater than the first germanium percentage. A silicon cap substantially free from germanium is over the second silicon germanium region.

Abstract: A method of forming a semiconductor device includes: forming a fin protruding above a substrate; forming a metal gate over the fin, the metal gate being surround by a dielectric layer; etching the metal gate to reduce a height of the metal gate, where after the etching, a recess is formed over the metal gate between gate spacers of the metal gate; lining sidewalls and a bottom of the recess with a semiconductor material; filling the recess by forming a dielectric material over the semiconductor material; forming a mask layer over the metal gate, where a first opening of the mask layer is directly over a portion of the dielectric layer adjacent to the metal gate; removing the portion of the dielectric layer to form a second opening in the dielectric layer, the second opening exposing an underlying source/drain region; and filling the second opening with a conductive material.

Abstract: A semiconductor device includes a substrate, a gate structure on the substrate, a source/drain (S/D) region and a contact. The S/D region is located in the substrate and on a side of the gate structure. The contact lands on and connected to the S/D region. The contact wraps around the S/D region.

Abstract: A device includes a fin extending from a semiconductor substrate; a gate stack over the fin; a spacer on a sidewall of the gate stack; a source/drain region in the fin adjacent the spacer; an inter-layer dielectric layer (ILD) extending over the gate stack, the spacer, and the source/drain region; a contact plug extending through the ILD and contacting the source/drain region; a dielectric layer including a first portion on a top surface of the ILD and a second portion extending between the ILD and the contact plug, wherein a top surface of the second portion is closer to the substrate than the top surface of the ILD; and an air gap between the spacer and the contact plug, wherein the second portion of the dielectric layer seals the top of the air gap.

Abstract: A method includes placing a wafer into a process chamber, and depositing a silicon nitride layer on a base layer of the wafer. The process of depositing the silicon nitride layer includes introducing a silicon-containing precursor into the process chamber, purging the silicon-containing precursor from the process chamber, introducing hydrogen radicals into the process chamber, purging the hydrogen radicals from the process chamber; introducing a nitrogen-containing precursor into the process chamber, and purging the nitrogen-containing precursor from the process chamber.