Abstract: A method includes providing a semiconductor structure having a mandrel layer and a hardmask layer disposed above a dielectric layer. A mandrel cell is patterned into the mandrel layer. An opening is etched into the hardmask layer. The opening is self-aligned with a sidewall of the mandrel. A refill layer is disposed over the structure and recessed down to a level that is below a top surface of the hardmask layer to form an opening plug that covers a bottom of the opening. The mandrel cell is utilized to form a metal line cell into the dielectric layer, the metal line cell having metal lines and a minimum line cell pitch. The opening plug is utilized to form a continuity cut in a metal line of the metal line cell. The continuity cut has a length that is larger than the minimum line cell pitch.

Abstract: A method of fabricating a FinFET device includes a self-aligned contact etch where a source/drain contact module is performed prior to a replacement metal gate (RMG) module. In particular, the method involves forming a sacrificial gate over the channel region of a fin, and an interlayer dielectric over adjacent source/drain regions of the fin. An etch mask is then used to protect source/drain contact regions and enable the removal of the interlayer dielectric from outside of the protected area, e.g., between adjacent fins.

Abstract: Provided are approaches for forming merged gate and source/drain (S/D) contacts in a semiconductor device. Specifically, one approach provides a dielectric layer over a set of gate structures formed over a substrate; a set of source/drain (S/D) openings patterned in the dielectric layer between the gate structures; a fill material formed over the gate structures, including within the S/D openings; and a set of gate openings patterned over the gate structures, wherein a portion of the dielectric layer directly adjacent the fill material formed within one of the S/D openings is removed. The fill material is then removed, selective to the dielectric layer, and a metal material is deposited over the semiconductor device to form a set of gate contacts within the gate openings, and a set of S/D contacts within the S/D openings, wherein one of the gate contacts and one of the S/D contacts are merged.

Abstract: The disclosed technology generally relates to semiconductor fabrication, and more particularly to a method of defining routing tracks for a standard cell semiconductor device, and to the standard cell semiconductor device fabricated using the method. In one aspect, a method of defining routing tracks in a target layer over a standard cell semiconductor device includes forming mandrels and forming a first set and a second set of spacers for defining the routing tracks. The standard cell semiconductor device includes a device layer and the routing tracks for contacting a device layer. The routing tracks include at least two pairs of off-center routing tracks, a central routing track arranged between the pairs of off-center routing tracks, and at least two edge tracks arranged on opposing sides of the at least two pairs of off-center routing tracks.

Abstract: A method of fabricating a FinFET device includes a self-aligned contact etch where a source/drain contact module is performed prior to a replacement metal gate (RMG) module. In particular, the method involves forming a sacrificial gate over the channel region of a fin, and an interlayer dielectric over adjacent source/drain regions of the fin. An etch mask is then used to protect source/drain contact regions and enable the removal of the interlayer dielectric from outside of the protected area, e.g., between adjacent fins. A sacrificial cobalt layer is used to backfill the cavities formed by etching the interlayer dielectric prior to forming a functional gate.

Abstract: A method includes forming at least one fin in a semiconductor substrate. A fin spacer is formed on at least a first portion of the at least one fin. The fin spacer has an upper surface. The at least one fin is recessed to thereby define a recessed fin with a recessed upper surface that it is at a level below the upper surface of the fin spacer. A first epitaxial material is formed on the recessed fin. A lateral extension of the first epitaxial material is constrained by the fin spacer. A cap layer is formed on the first epitaxial material. The fin spacer is removed. The cap layer protects the first epitaxial material during the removal of the fin spacer.

Abstract: A semiconductor cell includes a dielectric layer. An array of parallel metal lines is disposed in a longitudinal direction within the dielectric layer. The metal lines having line widths that are substantially equal to or greater than a predetermined minimum line width. Line spacers are disposed between the metal lines. The line spacers having line spacer widths that are substantially equal to or greater than a predetermined minimum line spacer width. The array of metal lines includes a signal line having a continuity cut disposed across its entire line width and a power line adjacent the signal line. The power line has a line width that is greater than twice the minimum line width. The power line has a notch disposed partially across its line width. The notch is aligned with the continuity cut in a direction perpendicular to the longitudinal direction of the metal lines.

Abstract: At least one method, apparatus and system disclosed herein for forming a finFET device having a pass-through structure. A first gate structure and a second gate structure are formed on a semiconductor wafer. A first active area is formed on one end of the first and second gate structures. A second active area is formed on the other end of the first and second gate structures. A trench silicide (TS) structure self-aligned to the first and second gate structures is formed. The TS structure is configured to operatively couple the first active area to the second active area.

Abstract: One method disclosed herein includes, among other things, forming a process layer on a substrate. A patterned mask layer is formed above the process layer. The patterned mask layer includes first openings exposing portions of the process layer. A carbon-containing silicon dioxide layer is formed above the patterned mask layer and in the first openings. The carbon-containing silicon dioxide layer is planarized to remove portions extending outside the first openings and generate a plurality of mask elements from remaining portions of the carbon-containing silicon dioxide layer. The patterned mask layer is removed. The process layer is etched using the mask elements as an etch mask.

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 of lithographically cutting a Mx line before the Mx line is lithographically defined by patterning and the resulting 2DSAV device are provided. Embodiments include forming an a-Si dummy metal layer over a SiO2 layer; forming a first softmask stack over the a-Si dummy metal layer; patterning a plurality of vias through the first softmask stack down to the SiO2 layer; removing the first soft mask stack; forming first and second etch stop layers over the a-Si dummy metal layer, the first etch stop layer formed in the plurality of vias; forming a-Si mandrels on the second etch stop layer; forming oxide spacers on opposite sides of each a-Si mandrel; removing the a-Si mandrels; forming a-Si dummy metal lines in the a-Si dummy metal layer below the oxide spacers; and forming a SiOC layer between the a-Si dummy metal lines.

Abstract: A method including providing a semiconductor structure having a dielectric stack, hardmask stack, and mandrel layer disposed thereon. An array of mandrels is patterned into the mandrel layer. Mandrel spacers are formed self-aligned on sidewalls of the mandrels. A gapfill layer is disposed and planarized over the semiconductor structure. Non-mandrel pillars are formed over the planarized gapfill layer. Exposed portions of the gapfill layer are etched to form non-mandrel plugs preserved by the pillars. The pillars are removed to form a pattern, the pattern including the non-mandrel plugs. The pattern is utilized to form an array of alternating mandrel and non-mandrel metal interconnection lines in the dielectric stack. The array includes non-mandrel dielectric structures formed from the non-mandrel plugs.

Abstract: A method includes forming first and second contact openings in a first dielectric layer. At least the first contact opening is at least partially lined with a liner layer. A first conductive feature is formed in the first contact opening and a second conductive feature is formed in the second contact opening. A portion of the liner layer adjacent a top surface of the first dielectric layer is removed to define a recess. A barrier layer is formed above the first dielectric layer and in the recess. The barrier layer has a first dielectric constant greater than a second dielectric constant of the first dielectric layer. A second dielectric layer is formed above the barrier layer. A third conductive feature is formed embedded in the second dielectric layer and contacting the second conductive feature.

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 includes providing a structure having a first hardmask layer, second hardmask layer and mandrel layer disposed respectively over a dielectric stack. An array of mandrels is patterned into the mandrel layer. A gamma trench is patterned into the second hardmask layer and between the mandrels. Self-aligned inner spacers are formed on sidewalls of the gamma trench, the inner spacers forming a portion of a pattern. The pattern is etched into the dielectric stack to form an array of alternating mandrel and non-mandrel metal lines extending in a Y direction and being self-aligned in a perpendicular X direction. The portion of the pattern formed by the inner spacers is utilized to form a pair of non-mandrel line cuts in a non-mandrel line. The non-mandrel line cuts are self-aligned in the Y direction.

Abstract: A method of fabricating a FinFET device includes a self-aligned contact etch where a source/drain contact module is performed prior to a replacement metal gate (RMG) module. In particular, the method involves forming a sacrificial gate over the channel region of a fin, and an interlayer dielectric over adjacent source/drain regions of the fin. An etch mask is then used to protect source/drain contact regions and enable the removal of the interlayer dielectric from outside of the protected area, e.g., between adjacent fins.

Abstract: At least one method, apparatus and system disclosed herein for forming a finFET device having a pass-through structure. A first gate structure and a second gate structure are formed on a semiconductor wafer. A first active area is formed on one end of the first and second gate structures. A second active area is formed on the other end of the first and second gate structures. A trench silicide (TS) structure self-aligned to the first and second gate structures is formed. The TS structure is configured to operatively couple the first active area to the second active area.

Abstract: A method includes providing a structure having a first, second and third hardmask layer and a mandrel layer disposed respectively over a dielectric stack. An array of mandrels, a beta trench and a gamma trench are patterned into the structure. First inner spacers are formed on sidewalls of the beta trench and second inner spacers are formed on sidewalls of the gamma trench. The first and second inner spacers form a portion of a pattern. The pattern is etched into the dielectric stack to form an array of mandrel and non-mandrel metal lines extending in a Y direction and being self-aligned in an X direction. The portion of the pattern formed by the first and second inner spacers forms a first pair of cuts in a mandrel line and a second pair of cuts in a non-mandrel line respectively. The cuts are self-aligned in the Y direction.

Abstract: A method for forming a pattern for interconnection lines and associated continuity dielectric blocks in an integrated circuit includes providing a structure having a mandrel layer disposed over an etch mask layer, the etch mask layer being disposed over a pattern layer and the pattern layer being disposed over a dielectric stack. Patterning an array of mandrels in the mandrel layer. Selectively etching a beta trench entirely in a mandrel of the array, the beta trench overlaying a beta block mask portion of the pattern layer. Selectively etching a gamma trench entirely in the etch mask layer, the gamma trench overlaying a gamma block mask portion of the pattern layer. Selectively etching the structure to form a pattern in the pattern layer, the pattern including the gamma and beta block mask portions.

Abstract: A method includes providing a semiconductor structure having a substrate including a longitudinally extending plurality of fins formed thereon. A target layout pattern is determined, which overlays active areas devices disposed on the fins. The target layout pattern includes a first group of sections overlaying devices having more fins than adjacent devices and a second group of sections overlaying devices having less fins than adjacent devices. A first extended exposure pattern is patterned into the structure, and includes extensions that extend sections of the first group toward adjacent sections of the first group. A second extended exposure pattern is patterned into the structure, and includes extensions that extend sections of the second group toward adjacent sections of the second group. Portions of the first and second extended exposure patterns are combined to form a final pattern overlaying the same active areas as the target pattern.