Abstract: A method and structure for mitigating leakage current in devices that include a continuous active region. In some embodiments, a threshold voltage at the cell boundary is increased by changing a photomask logic operation (LOP) to reverse a threshold voltage type at the cell boundary. Alternatively, in some cases, the threshold voltage at the cell boundary is increased by performing a threshold voltage implant (e.g., an ion implant) at the cell boundary, and into a dummy gate disposed at the cell boundary. Further, in some embodiments, the threshold voltage at the cell boundary is increased by use of a silicon germanium (SiGe) channel at the cell boundary. In some cases, the SiGe may be disposed within the substrate at the cell boundary and/or the SiGe may be part of the dummy gate disposed at the cell boundary.

Abstract: A mandrel is formed over an active region that includes a first region and a second region. The first region and the second region are reserved for the formation of a source and a drain of a FinFET, respectively. A portion of the mandrel formed over the second region is broken up into a first segment and a second segment separated from the first segment by a gap. Spacers are formed on opposite sides of the mandrel. Using the spacers, fins are defined. The fins protrude upwardly out of the active region. A portion of the second region corresponding to the gap has no fins formed thereover. The source is epitaxially grown on the fins in the first region. At least a portion of the drain is epitaxially grown on the portion of the second region having no fins.

Abstract: A method and structure for mitigating strain loss (e.g., in a FinFET channel) includes providing a semiconductor device having a substrate having a substrate fin portion, an active fin region formed over a first part of the substrate fin portion, a pickup region formed over a second part of the substrate fin portion, and an anchor formed over a third part of the substrate fin portion. In some embodiments, the substrate fin portion includes a first material, and the active fin region includes a second material different than the first material. In various examples, the anchor is disposed between and adjacent to each of the active fin region and the pickup region.

Abstract: A conductive line structure includes two conductive lines in a layout. The two cut lines are over at least a part of the two conductive lines in the layout. The cut lines designate cut sections of the two conductive lines and the cut lines are spaced from each other within a fabrication process limit. The two cut lines are connected in the layout. The two conductive lines are patterned over a substrate in a physical integrated circuit using the two connected parallel cut lines. The two conductive lines are electrically conductive.

Abstract: The present disclosure provides a method for fabricating an integrated circuit (IC). The method includes receiving an IC layout having active regions, conductive contact features landing on the active regions, and a conductive via feature to be landing on a first subset of the conductive contact features and to be spaced from a second subset of the conductive contact features; evaluating a spatial parameter of the conductive via feature to the conductive contact features; and modifying the IC layout according to the spatial parameter such that the conductive via feature has a S-curved shape.

Abstract: Various examples of integrated circuit layouts with line-end extensions are disclosed herein. In an example, a method includes receiving an integrated circuit layout that contains: a first and second set of shapes extending in parallel in a first direction, wherein a pitch of the first set of shapes is different from a pitch of the second set of shapes. A cross-member shape is inserted into the integrated circuit layout that extends in a second direction perpendicular to the first direction, and a set of line-end extensions is inserted into the integrated circuit layout that extend from each shape of the first set of shapes and the second set of shapes to the cross-member shape. The integrated circuit layout containing the first set of shapes, the second set of shapes, the cross-member shape, and the set of line-end extensions is provided for fabricating an integrated circuit.

Abstract: A method and structure for mitigating leakage current in devices that include a continuous active region. In some embodiments, a threshold voltage at the cell boundary is increased by changing a photomask logic operation (LOP) to reverse a threshold voltage type at the cell boundary. Alternatively, in some cases, the threshold voltage at the cell boundary is increased by performing a threshold voltage implant (e.g., an ion implant) at the cell boundary, and into a dummy gate disposed at the cell boundary. Further, in some embodiments, the threshold voltage at the cell boundary is increased by use of a silicon germanium (SiGe) channel at the cell boundary. In some cases, the SiGe may be disposed within the substrate at the cell boundary and/or the SiGe may be part of the dummy gate disposed at the cell boundary.

Abstract: A method and structure for mitigating strain loss (e.g., in a FinFET channel) includes providing a semiconductor device having a substrate having a substrate fin portion, an active fin region formed over a first part of the substrate fin portion, a pickup region formed over a second part of the substrate fin portion, and an anchor formed over a third part of the substrate fin portion. In some embodiments, the substrate fin portion includes a first material, and the active fin region includes a second material different than the first material. In various examples, the anchor is disposed between and adjacent to each of the active fin region and the pickup region.

Abstract: A method and structure for mitigating strain loss (e.g., in a FinFET channel) includes providing a semiconductor device having a substrate having a substrate fin portion, an active fin region formed over a first part of the substrate fin portion, a pickup region formed over a second part of the substrate fin portion, and an anchor formed over a third part of the substrate fin portion. In some embodiments, the substrate fin portion includes a first material, and the active fin region includes a second material different than the first material. In various examples, the anchor is disposed between and adjacent to each of the active fin region and the pickup region.

Abstract: In a method of forming an integrated circuit (IC) layout, an empty region in the IC layout is identified by a processor circuit, wherein the empty region is a region of the IC layout not including any active fins. A first portion of the empty region is filled with a first plurality of dummy fin cells, wherein each of the first plurality of dummy fin cells is based on a first standard dummy fin cell, and wherein the first standard dummy fin cell has a first gate width and comprises a first plurality of partitions. A second portion of the empty region is filled with a second plurality of dummy fin cells, wherein each of the second plurality of dummy fin cells is based on a second standard dummy fin cell, and wherein the second standard dummy fin cell has a second gate width and comprises a second plurality of partitions.

Abstract: A semiconductor device includes a fin structure, first and second gate structures, a source/drain region, a source/drain contact, a separator, a plug contacting the source/drain contact and a wiring contacting the plug. The fin structure protrudes from an isolation insulating layer and extends in a first direction. The first and second gate structures are formed over the fin structure and extend in a second direction crossing the first direction. The source/drain region is disposed between the first and second gate structures. The interlayer insulating layer is disposed over the fin structure, the first and second gate structures and the source/drain region. The first source/drain contact is disposed on the first source/drain region. The separator is disposed adjacent to the first source/drain contact layer. Ends of the first and second gate structures and an end of the source drain contact are in contact with a same face of the separator.

Abstract: A semiconductor device includes a fin structure, first and second gate structures, a source/drain region, a source/drain contact layer and a separation layer. The fin structure protrudes from an isolation insulating layer disposed over a substrate and extends in a first direction. The first and second gate structures are formed over the fin structure and extend in a second direction crossing the first direction. The source/drain region is disposed between the first and second gate structures. The interlayer insulating layer is disposed over the fin structure, the first and second gate structures and the source/drain region. The first source/drain contact layer is disposed on the first source/drain region. The separation layer is disposed adjacent to the first source/drain contact layer. Ends of the first and second gate structures and an end of the source drain contact layer are in contact with a same face of the separation layer.

Abstract: In a method of forming an integrated circuit (IC) layout, an empty region in the IC layout is identified by a processor circuit, wherein the empty region is a region of the IC layout not including any active fins. A first portion of the empty region is filled with a first plurality of dummy fin cells, wherein each of the first plurality of dummy fin cells is based on a first standard dummy fin cell, and wherein the first standard dummy fin cell has a first gate width and comprises a first plurality of partitions. A second portion of the empty region is filled with a second plurality of dummy fin cells, wherein each of the second plurality of dummy fin cells is based on a second standard dummy fin cell, and wherein the second standard dummy fin cell has a second gate width and comprises a second plurality of partitions.

Abstract: A semiconductor device and method includes: forming a first fin and a second fin on a substrate; forming a dummy gate material over the first fin and the second fin; forming a recess in the dummy gate material between the first fin and the second fin; forming a sacrificial oxide on sidewalls of the dummy gate material in the recess; filling an insulation material between the sacrificial oxide on the sidewalls of the dummy gate material in the recess; removing the dummy gate material and the sacrificial oxide; and forming a first replacement gate over the first fin and a second replacement gate over the second fin.

Abstract: The present disclosure describes an exemplary replacement gate process that forms spacer layers in a gate stack to mitigate time dependent dielectric breakdown (TDDB) failures. For example, the method can include a partially fabricated gate structure with a first recess. A spacer layer is deposited into the first recess and etched with an anisotropic etchback (EB) process to form a second recess that has a smaller aperture than the first recess. A metal fill layer is deposited into the second recess.

Abstract: Provided is a metal gate structure and related methods that include forming a first fin and a second fin on a substrate. In various embodiments, the first fin has a first gate region and the second fin has a second gate region. By way of example, a metal-gate line is formed over the first and second gate regions. In some embodiments, the metal-gate line extends from the first fin to the second fin, and the metal-gate line includes a sacrificial metal portion. In various examples, a line-cut process is performed to separate the metal-gate line into a first metal gate line and a second gate line. In some embodiments, the sacrificial metal portion prevents lateral etching of a dielectric layer during the line-cut process.

Abstract: A semiconductor device and method includes: forming a first fin and a second fin on a substrate; forming a dummy gate material over the first fin and the second fin; forming a recess in the dummy gate material between the first fin and the second fin; forming a sacrificial oxide on sidewalls of the dummy gate material in the recess; filling an insulation material between the sacrificial oxide on the sidewalls of the dummy gate material in the recess; removing the dummy gate material and the sacrificial oxide; and forming a first replacement gate over the first fin and a second replacement gate over the second fin.

Abstract: Provided is a metal gate structure and related methods that include forming a first fin and a second fin on a substrate. In various embodiments, the first fin has a first gate region and the second fin has a second gate region. By way of example, a metal-gate line is formed over the first and second gate regions. In some embodiments, the metal-gate line extends from the first fin to the second fin, and the metal-gate line includes a sacrificial metal portion. In various examples, a line-cut process is performed to separate the metal-gate line into a first metal gate line and a second gate line. In some embodiments, the sacrificial metal portion prevents lateral etching of a dielectric layer during the line-cut process.

Abstract: A post placement abutment treatment for cell row design is provided. In an embodiment a first cell and a second cell are placed in a first cell row and a third cell and a fourth cell are placed into a second cell row. After placement vias connecting power and ground rails to the underlying structures are analyzed to determine if any can be merged or else removed completely. By merging and removing the closely placed vias, the physical limitations of photolithography may be by-passed, allowing for smaller structures to be formed.

Abstract: Provided is a metal gate structure and related methods that include forming a first fin and a second fin on a substrate. In various embodiments, the first fin has a first gate region and the second fin has a second gate region. By way of example, a metal-gate line is formed over the first and second gate regions. In some embodiments, the metal-gate line extends from the first fin to the second fin, and the metal-gate line includes a sacrificial metal portion. In various examples, a line-cut process is performed to separate the metal-gate line into a first metal gate line and a second gate line. In some embodiments, the sacrificial metal portion prevents lateral etching of a dielectric layer during the line-cut process.