A semiconductor device includes a substrate including a first fin element, a second fin element, and a third fin element. A first source/drain epitaxial feature is disposed over the first and second fin elements. A first portion of the first source/drain epitaxial feature disposed on the first fin element and a second portion of the first source/drain epitaxial feature disposed on the second fin element merge at a merge point. A second source/drain epitaxial feature is disposed over the third fin element. A first sidewall of the second source/drain epitaxial feature interfaces a first third-fin spacer disposed along a first sidewall of the third fin element. A second sidewall of the second source/drain epitaxial feature interfaces a second third-fin spacer disposed along a second sidewall of the third fin element. The merge point has a first height less than a second height of the first third-fin spacer.

An integrated circuit product includes two laterally spaced-apart transistors, wherein each of the two laterally spaced-apart transistors includes a gate structure, a gate cap layer positioned above the gate structure, and a sidewall spacer positioned adjacent to sidewalls of the gate structure. A source/drain region is positioned between the two laterally spaced-apart transistors, and a conformal etch stop layer is positioned on and in contact with an upper surface of the source/drain region and on and in contact with a sidewall surface of the sidewall spacer of each of the two laterally spaced-apart transistors. A self-aligned conductive contact extends through an opening in the conformal etch stop layer and is conductively coupled to the source/drain region.

A method to form a semiconductor structure with an active region and a compatible dielectric layer is described. In one embodiment, a semiconductor structure has a dielectric layer comprised of an oxide of a first semiconductor material, wherein a second (and compositionally different) semiconductor material is formed between the dielectric layer and the first semiconductor material. In another embodiment, a portion of the second semiconductor material is replaced with a third semiconductor material in order to impart uniaxial strain to the lattice structure of the second semiconductor material.

A semiconductor device includes a gate, which comprises a gate electrode and a gate dielectric underlying the gate electrode, a spacer formed on a sidewall of the gate electrode and the gate dielectric, a buffer layer having a first portion underlying the gate dielectric and the spacer and a second portion adjacent the spacer wherein the top surface of the second portion of the buffer layer is recessed below the top surface of the first portion of the buffer layer, and a source/drain region substantially aligned with the spacer. The buffer layer preferably has a greater lattice constant than an underlying semiconductor substrate. The semiconductor device may further include a semiconductor-capping layer between the buffer layer and the gate dielectric, wherein the semiconductor-capping layer has a smaller lattice constant then the buffer layer.

A fin field effect transistor (FinFET) comprises a substrate; a fin over the substrate, the fin having a channel region; a gate structure engaging the fin adjacent to the channel region; and a spacer on sidewalls of the gate structure. The FinFET further includes first and second heavily doped source/drain (HDD) features at least partially in the fin, on opposing sides of the gate structure, and adjacent to the spacer. The FinFET further includes first and second lightly doped source/drain (LDD) regions in the fin between the first and second HDD features, respectively, and the channel region. A sidewall of the first HDD feature and a sidewall of the first LDD region have substantially a same shape.

A method of forming a gate structure, including forming one or more vertical fins on a substrate; forming a bottom spacer on the substrate surface adjacent to the one or more vertical fins; forming a gate structure on at least a portion of the sidewalls of the one or more vertical fins; forming a gauge layer on at least a portion of the bottom spacer, wherein the gauge layer covers at least a portion of the gate structure on the sidewalls of the one or more vertical fins; and removing a portion of the gauge layer on the bottom spacer.

A semiconductor device may include the following elements: a fin member including a first doped portion, a second doped portion, and a semiconductor portion positioned between the first doped portion and the second doped portion; a composite structure including a conductor and an insulator positioned between the conductor and the semiconductor portion in a first direction; a first spacer having a first dielectric constant and positioned close to the second doped portion; a second spacer having a second dielectric constant and positioned close to the first doped portion; and a third spacer having a third dielectric constant. The second spacer is positioned between the third spacer and the fin member in the first direction. The composite structure is positioned between the first spacer and the second spacer. The first dielectric constant is less than at least one of the second dielectric constant and the third dielectric constant.

At least one method, apparatus and system disclosed herein for suppressing over-growth of epitaxial layer formed on fins of fin field effect transistor (finFET) to prevent shorts between fins of separate finFET devices. A set of fins of a first transistor is formed. The set of fins comprises a first outer fin, an inner fin, and a second outer fin. An oxide deposition process is performed for depositing an oxide material upon the set of fins. A first recess process is performed for removing a portion of oxide material. This leaves a portion of the oxide material remaining on the inside walls of the first and second outer fins. A spacer nitride deposition process is performed. A spacer nitride removal process is performed, leaving spacer nitride material at the outer walls of the first and second outer fins. A second recess process is performed for removing the oxide material from the inside walls of the first and second outer fins. An epitaxial layer deposition processed upon the set of fins. A portion of the lateral over-growth of epitaxial layer on the outer walls of the first and second outer fins is suppressed by the spacer nitride material.

A method for forming a semiconductor device includes depositing a dielectric layer over fins formed in a semiconductor substrate. The dielectric layer includes a screen layer over tops of the fins. An etch stop feature is formed on the screen layer. The etch stop feature is patterned down to the screen layer in regions across the device. A dummy gate material formed over the fins is planarized down to the etch stop feature, a dielectric fill between gate structures patterned from the dummy gate material is planarized down to the etch stop feature and a gate conductor is planarized to the etch stop feature.

A transistor in an integrated circuit device is formed using fabrication processes that include techniques to create a strain in the channel material, thereby improving the performance of the transistor. In one or more embodiments, an initial transistor structure is formed including a substrate, a dummy fin, and a hard mask. The dummy fin structure is narrowed. A channel is epitaxially grown on the dummy fin structure to create a strain on the channel. A first gate stack is formed over the channel. The hard mask and dummy fin are removed. A second gate stack is formed over the channel. Excess material is removed from the second gate stack. The formation of the transistor is finalized using a variety of techniques.