Abstract: A device and method for forming a semiconductor device includes forming a gate structure on a channel region of fin structures and forming a flowable dielectric material on a source region portion and a drain region portion of the fin structures. The flowable dielectric material is present at least between adjacent fin structures of the plurality of fin structures filling a space between the adjacent fin structures. An upper surface of the source region portion and the drain region portion of fin structures is exposed. An epitaxial semiconductor material is formed on the upper surface of the source region portion and the drain region portion of the fin structures.

Abstract: A method, FET structure and gate cut structure are disclosed. The method forms a gate cut opening in a dummy gate in a gate material layer, the gate cut opening extending into a space separating a semiconductor structures on a substrate under the gate material layer. A source/drain region is formed on the semiconductor structure(s), and a gate cut isolation is formed in the gate cut opening. The gate cut isolation may include an oxide body. During forming of a contact, a mask has a portion covering an upper end of the gate cut isolation to protect it. The gate cut structure includes a gate cut isolation including a nitride liner contacting the end of the first metal gate conductor and the end of the second metal gate conductor, and an oxide body inside the nitride liner.

Abstract: A method, FET structure and gate cut structure are disclosed. The method forms a gate cut opening in a dummy gate in a gate material layer, the gate cut opening extending into a space separating a semiconductor structures on a substrate under the gate material layer. A source/drain region is formed on the semiconductor structure(s), and a gate cut isolation is formed in the gate cut opening. The gate cut isolation may include an oxide body. During forming of a contact, a mask has a portion covering an upper end of the gate cut isolation to protect it. The gate cut structure includes a gate cut isolation including a nitride liner contacting the end of the first metal gate conductor and the end of the second metal gate conductor, and an oxide body inside the nitride liner.

Abstract: A third type of metal gate stack is provided above an isolation structure and between a replacement metal gate n-type field effect transistor and a replacement metal gate p-type field effect transistor. The third type of metal gate stack includes at least three different components. Notably, the third type of metal gate stack includes, as a first component, an n-type workfunction metal layer, as a second component, a p-type workfunction metal layer, and as a third component, a low resistance metal layer. In some embodiments, the uppermost surface of the first, second and third components of the third type of metal gate stack are all substantially coplanar with each other. In other embodiments, an uppermost surface of the third component of the third type of metal gate stack is non-substantially coplanar with an uppermost surface of both the first and second components of the third type of metal gate stack.

Abstract: Embodiments of the disclosure provides an apparatus for aligning layers of an integrated circuit (IC), the apparatus including: an insulator layer positioned above a semiconductor substrate; a first diffraction grating within a first region of the insulator layer, the first diffraction grating including a first grating material within the first region of the insulator layer; and a second diffraction grating within a second region of the insulator layer, the second grating including a second grating material within the second region of the insulator layer, wherein the second grating material is different from the first grating material, and wherein an optical contrast between the first and second grating materials is greater than an optical contrast between the second grating material and the insulator layer.

Abstract: Embodiments of the disclosure provides an apparatus for aligning layers of an integrated circuit (IC), the apparatus including: an insulator layer positioned above a semiconductor substrate; a first diffraction grating within a first region of the insulator layer, the first diffraction grating including a first grating material within the first region of the insulator layer; and a second diffraction grating within a second region of the insulator layer, the second grating including a second grating material within the second region of the insulator layer, wherein the second grating material is different from the first grating material, and wherein an optical contrast between the first and second grating materials is greater than an optical contrast between the second grating material and the insulator layer.

Abstract: A method forming a semiconductor device that in one embodiment includes forming a gate structure on a channel region of fin structures, and forming a flowable dielectric material on a source region portion and a drain region portion of the fin structures. The flowable dielectric material is present at least between adjacent fin structures of the plurality of fin structures filling a space between the adjacent fin structures. An upper surface of the source region portion and the drain region portion of fin structures is exposed. An epitaxial semiconductor material is formed on the upper surface of the source region portion and the drain region portion of the fin structures.

Abstract: A device and method for forming a semiconductor device includes forming a gate structure on a channel region of fin structures and forming a flowable dielectric material on a source region portion and a drain region portion of the fin structures. The flowable dielectric material is present at least between adjacent fin structures of the plurality of fin structures filling a space between the adjacent fin structures. An upper surface of the source region portion and the drain region portion of fin structures is exposed. An epitaxial semiconductor material is formed on the upper surface of the source region portion and the drain region portion of the fin structures.

Abstract: A third type of metal gate stack is provided above an isolation structure and between a replacement metal gate n-type field effect transistor and a replacement metal gate p-type field effect transistor. The third type of metal gate stack includes at least three different components. Notably, the third type of metal gate stack includes, as a first component, an n-type workfunction metal layer, as a second component, a p-type workfunction metal layer, and as a third component, a low resistance metal layer. In some embodiments, the uppermost surface of the first, second and third components of the third type of metal gate stack are all substantially coplanar with each other. In other embodiments, an uppermost surface of the third component of the third type of metal gate stack is non-substantially coplanar with an uppermost surface of both the first and second components of the third type of metal gate stack.

Abstract: The present disclosure relates to methods for forming IC structures having recessed gate spacers and related IC structures. A method may include: forming a first and second dummy gate over a fin, each dummy gate having gate spacers disposed on sidewalls thereof such that an opening is disposed between a first gate spacer and a second gate spacer, the opening exposing a source/drain region; recessing the first and second gate spacers; forming an etch stop layer within the opening such that the etch stop layer extends vertically along the recessed first and second gate spacers; forming a dielectric fill over the etch stop layer to substantially fill the opening; replacing the first and second dummy gates with first and second RMG structures; recessing the first and second RMG structures; and forming a gate cap layer over the first and second RMG structures.

Abstract: A third type of metal gate stack is provided above an isolation structure and between a replacement metal gate n-type field effect transistor and a replacement metal gate p-type field effect transistor. The third type of metal gate stack includes at least three different components. Notably, the third type of metal gate stack includes, as a first component, an n-type workfunction metal layer, as a second component, a p-type workfunction metal layer, and as a third component, a low resistance metal layer. In some embodiments, the uppermost surface of the first, second and third components of the third type of metal gate stack are all substantially coplanar with each other. In other embodiments, an uppermost surface of the third component of the third type of metal gate stack is non-substantially coplanar with an uppermost surface of both the first and second components of the third type of metal gate stack.

Abstract: A method forming a semiconductor device that in one embodiment includes forming a gate structure on a channel region of fin structures, and forming a flowable dielectric material on a source region portion and a drain region portion of the fin structures. The flowable dielectric material is present at least between adjacent fin structures of the plurality of fin structures filling a space between the adjacent fin structures. An upper surface of the source region portion and the drain region portion of fin structures is exposed. An epitaxial semiconductor material is formed on the upper surface of the source region portion and the drain region portion of the fin structures.

Abstract: One aspect of the disclosure relates to an integrated circuit structure. The integrated circuit structure may include: a contact line being disposed within a dielectric layer and providing electrical connection to source/drain epitaxial regions surrounding a set of fins, the contact line including: a first portion of the contact line electrically isolated from a second portion of the contact line by a contact line spacer, wherein the first portion and the second portion each include a liner layer and a metal, the liner layer separating the metal from the dielectric layer and the source/drain epitaxial regions, and wherein the metal is directly in contact with the contact line spacer.

Abstract: A method forming a semiconductor device that in one embodiment includes forming a gate structure on a channel region of fin structures, and forming a flowable dielectric material on a source region portion and a drain region portion of the fin structures. The flowable dielectric material is present at least between adjacent fin structures of the plurality of fin structures filling a space between the adjacent fin structures. An upper surface of the source region portion and the drain region portion of fin structures is exposed. An epitaxial semiconductor material is formed on the upper surface of the source region portion and the drain region portion of the fin structures.

Abstract: A method forming a semiconductor device that in one embodiment includes forming a gate structure on a channel region of fin structures, and forming a flowable dielectric material on a source region portion and a drain region portion of the fin structures. The flowable dielectric material is present at least between adjacent fin structures of the plurality of fin structures filling a space between the adjacent fin structures. An upper surface of the source region portion and the drain region portion of fin structures is exposed. An epitaxial semiconductor material is formed on the upper surface of the source region portion and the drain region portion of the fin structures.

Abstract: One aspect of the disclosure relates to an integrated circuit structure. The integrated circuit structure may include: a contact line being disposed within a dielectric layer and providing electrical connection to source/drain epitaxial regions surrounding a set of fins, the contact line including: a first portion of the contact line electrically isolated from a second portion of the contact line by a contact line spacer, wherein the first portion and the second portion each include a liner layer and a metal, the liner layer separating the metal from the dielectric layer and the source/drain epitaxial regions, and wherein the metal is directly in contact with the contact line spacer.

Abstract: One aspect of the disclosure relates to an integrated circuit structure. The integrated circuit structure may include: a contact line being disposed within a dielectric layer and providing electrical connection to source/drain epitaxial regions surrounding a set of fins, the contact line including: a first portion of the contact line electrically isolated from a second portion of the contact line by a contact line spacer, wherein the first portion and the second portion each include a liner layer and a metal, the liner layer separating the metal from the dielectric layer and the source/drain epitaxial regions, and wherein the metal is directly in contact with the contact line spacer.

Abstract: One aspect of the disclosure relates to an integrated circuit structure. The integrated circuit structure may include: a contact line being disposed within a dielectric layer and providing electrical connection to source/drain epitaxial regions surrounding a set of fins, the contact line including: a first portion of the contact line electrically isolated from a second portion of the contact line by a contact line spacer, wherein the first portion and the second portion each include a liner layer and a metal, the liner layer separating the metal from the dielectric layer and the source/drain epitaxial regions, and wherein the metal is directly in contact with the contact line spacer.

Abstract: A third type of metal gate stack is provided above an isolation structure and between a replacement metal gate n-type field effect transistor and a replacement metal gate p-type field effect transistor. The third type of metal gate stack includes at least three different components. Notably, the third type of metal gate stack includes, as a first component, an n-type workfunction metal layer, as a second component, a p-type workfunction metal layer, and as a third component, a low resistance metal layer. In some embodiments, the uppermost surface of the first, second and third components of the third type of metal gate stack are all substantially coplanar with each other. In other embodiments, an uppermost surface of the third component of the third type of metal gate stack is non-substantially coplanar with an uppermost surface of both the first and second components of the third type of metal gate stack.

Abstract: A third type of metal gate stack is provided above an isolation structure and between a replacement metal gate n-type field effect transistor and a replacement metal gate p-type field effect transistor. The third type of metal gate stack includes at least three different components. Notably, the third type of metal gate stack includes, as a first component, an n-type workfunction metal layer, as a second component, a p-type workfunction metal layer, and as a third component, a low resistance metal layer. In some embodiments, the uppermost surface of the first, second and third components of the third type of metal gate stack are all substantially coplanar with each other. In other embodiments, an uppermost surface of the third component of the third type of metal gate stack is non-substantially coplanar with an uppermost surface of both the first and second components of the third type of metal gate stack.