Abstract: Conductive cap-based approaches for conductive via fabrication is described. In an example, an integrated circuit structure includes a plurality of conductive lines in an ILD layer above a substrate. Each of the conductive lines is recessed relative to an uppermost surface of the ILD layer. A plurality of conductive caps is on corresponding ones of the plurality of conductive lines, in recess regions above each of the plurality of conductive lines. A hardmask layer is on the plurality of conductive caps and on the uppermost surface of the ILD layer. The hardmask layer includes a first hardmask component on and aligned with the plurality of conductive caps, and a second hardmask component on an aligned with regions of the uppermost surface of the ILD layer. A conductive via is in an opening in the hardmask layer and on a conductive cap of one of the plurality of conductive lines.

Abstract: Methods and architectures for IC interconnect trenches, and trench plugs that define separations between two adjacent trench ends. Plugs and trenches may be defined through a multiple patterning process. An upper grating pattern may be summed with a plug keep pattern into a pattern accumulation layer. The pattern accumulation layer may be employed to define plug masks. A lower grating pattern may then be summed with the plug masks to define a pattern in a trench ILD material, which can then be backfilled with interconnect metallization. As such, a complex damascene interconnect structure can be fabricated at the scaled-down geometries achievable with pitch-splitting techniques. In some embodiments, the trenches are located at spaces between first spacer masks defined in a patterning process associated with the first grating pattern while the plug masks are located based on a tone-inversion of second spacer masks associated with the second grating pattern.

Abstract: Methods and architectures for IC interconnect trenches, and trench plugs that define separations between two adjacent trench ends. Plugs and trenches may be defined through a multiple patterning process. An upper grating pattern may be summed with a plug keep pattern into a pattern accumulation layer. The pattern accumulation layer may be employed to define plug masks. A lower grating pattern may then be summed with the plug masks to define a pattern in trench ILD material, which can then be backfilled with interconnect metallization. As such, a complex damascene interconnect structure can be fabricated at the scaled-down geometries achievable with pitch-splitting techniques. In some embodiments, the trenches are located at spaces between first spacer masks defined in a patterning process associated with the first grating pattern while the plug masks are located based on a tone-inversion of second spacer masks associated with the second grating pattern.

Abstract: Conductive via and metal line end fabrication is described. In an example, an interconnect structure includes a first inter-layer dielectric (ILD) on a hardmask layer, where the ILD includes a first ILD opening and a second ILD opening. The interconnect structure further includes an etch stop layer (ESL) on the ILD layer, where the ESL includes a first ESL opening aligned with the first ILD opening to form a first via opening, and where the ESL layer includes a second ESL opening aligned with the second ILD opening. The interconnect structure further includes a first via in the first via opening, a second ILD layer on the first ESL, and a metal line in the second ILD layer, where the metal line is in contact with the first via, and where the metal line includes a first metal opening, and where the metal line includes a second metal opening aligned with the second ILD opening and the ESL opening to form a second via opening.

Abstract: An integrated circuit structure includes a metal level comprising a plurality of interconnect lines along a first direction. A cell is on the metal level, wherein one or more of the plurality of interconnect lines that extend through the cell comprise a power shared track that is segmented inside the cell into one or more power segments and one or more signal segments so that both power and signals share a same track.

Abstract: Techniques are disclosed for providing a decoupled via fill. Given a via trench, a first barrier layer is conformally deposited onto the bottom and sidewalls of the trench. A first metal fill is blanket deposited into the trench. The non-selective deposition is subsequently recessed so that only a portion of the trench is filled with the first metal. The previously deposited first barrier layer is removed along with the first metal, thereby re-exposing the upper sidewalls of the trench. A second barrier layer is conformally deposited onto the top of the first metal and the now re-exposed trench sidewalls. A second metal fill is blanket deposited into the remaining trench. Planarization and/or etching can be carried out as needed for subsequent processing. Thus, a methodology for filling high aspect ratio vias using a dual metal process is provided. Note, however, the first and second fill metals may be the same.

Abstract: Techniques are disclosed for forming a logic device including integrated spin-transfer torque magnetoresistive random-access memory (STT-MRAM). In accordance with some embodiments, one or more magnetic tunnel junction (MTJ) devices may be formed within a given back-end-of-line (BEOL) interconnect layer of a host logic device. A given MTJ device may be formed, in accordance with some embodiments, over an electrically conductive layer configured to serve as a pedestal layer for the MTJ's constituent magnetic and insulator layers. In accordance with some embodiments, one or more conformal spacer layers may be formed over sidewalls of a given MTJ device and attendant pedestal layer, providing protection from oxidation and corrosion. A given MTJ device may be electrically coupled with an underlying interconnect or other electrically conductive feature, for example, by another intervening electrically conductive layer configured to serve as a thin via, in accordance with some embodiments.

Abstract: An integrated circuit structure includes a metal level comprising a plurality of interconnect lines along a first direction. A cell is on the metal level, wherein one or more of the plurality of interconnect lines that extend through the cell comprise a power shared track that is segmented inside the cell into one or more power segments and one or more signal segments so that both power and signals share a same track.

Abstract: Conductive via and metal line end fabrication is described. In an example, an interconnect structure includes a first inter-layer dielectric (ILD) on a hardmask layer, where the ILD includes a first ILD opening and a second ILD opening. The interconnect structure further includes an etch stop layer (ESL) on the ILD layer, where the ESL includes a first ESL opening aligned with the first ILD opening to form a first via opening, and where the ESL layer includes a second ESL opening aligned with the second ILD opening. The interconnect structure further includes a first via in the first via opening, a second ILD layer on the first ESL, and a metal line in the second ILD layer, where the metal line is in contact with the first via, and where the metal line includes a first metal opening, and where the metal line includes a second metal opening aligned with the second ILD opening and the ESL opening to form a second via opening.

Abstract: Techniques are disclosed for insulating or electrically isolating select vias within a given interconnect layer, so a conductive routing can skip over those select isolated vias to reach other vias or interconnects in that same layer. Such a via blocking layer may be selectively implemented in any number of locations within a given interconnect as needed. Techniques for forming the via blocking layer are also provided, including a first methodology that uses a sacrificial passivation layer to facilitate selective deposition of insulator material that form the via blocking layer, a second methodology that uses spin-coating of wet-recessible polymeric formulations to facilitate selective deposition of insulator material that form the via blocking layer, and a third methodology that uses spin-coating of nanoparticle formulations to facilitate selective deposition of insulator material that form the via blocking layer. Harmful etching processes typically associated with conformal deposition processes is avoided.

Abstract: Techniques are disclosed for providing a decoupled via fill. Given a via trench, a first barrier layer is conformally deposited onto the bottom and sidewalls of the trench. A first metal fill is blanket deposited into the trench. The non-selective deposition is subsequently recessed so that only a portion of the trench is filled with the first metal. The previously deposited first barrier layer is removed along with the first metal, thereby re-exposing the upper sidewalls of the trench. A second barrier layer is conformally deposited onto the top of the first metal and the now re-exposed trench sidewalls. A second metal fill is blanket deposited into the remaining trench. Planarization and/or etching can be carried out as needed for subsequent processing. Thus, a methodology for filling high aspect ratio vias using a dual metal process is provided. Note, however, the first and second fill metals may be the same.

Abstract: A method including forming a dielectric layer on a contact point of an integrated circuit structure; forming a hardmask including a dielectric material on a surface of the dielectric layer; and forming at least one via in the dielectric layer to the contact point using the hardmask as a pattern. An apparatus including a circuit substrate including at least one active layer including a contact point; a dielectric layer on the at least one active layer; a hardmask including a dielectric material having a least one opening therein for an interconnect material; and an interconnect material in the at least one opening of the hardmask and through the dielectric layer to the contact point.

Abstract: An embodiment includes an apparatus comprising: a metal layer comprising a plurality of interconnect lines on a plurality of vias; an additional metal layer comprising first, second, and third interconnect lines on first, second, and third vias; the first and third vias coupling the first and third interconnect lines to two of the plurality of interconnect lines; a lateral interconnect, included entirely within the additional metal layer, directly connected to each of the first, second, and third interconnect lines; and an insulator layer included entirely between two sidewalls of the second via. Other embodiments are described herein.

Abstract: Conductive cap-based approaches for conductive via fabrication is described. In an example, an integrated circuit structure includes a plurality of conductive lines in an ILD layer above a substrate. Each of the conductive lines is recessed relative to an uppermost surface of the ILD layer. A plurality of conductive caps is on corresponding ones of the plurality of conductive lines, in recess regions above each of the plurality of conductive lines. A hardmask layer is on the plurality of conductive caps and on the uppermost surface of the ILD layer. The hardmask layer includes a first hardmask component on and aligned with the plurality of conductive caps, and a second hardmask component on an aligned with regions of the uppermost surface of the ILD layer. A conductive via is in an opening in the hardmask layer and on a conductive cap of one of the plurality of conductive lines.

Abstract: Techniques are disclosed for providing a decoupled via fill. Given a via trench, a first barrier layer is conformally deposited onto the bottom and sidewalls of the trench. A first metal fill is blanket deposited into the trench. The non-selective deposition is subsequently recessed so that only a portion of the trench is filled with the first metal. The previously deposited first barrier layer is removed along with the first metal, thereby re-exposing the upper sidewalls of the trench. A second barrier layer is conformally deposited onto the top of the first metal and the now re-exposed trench sidewalls. A second metal fill is blanket deposited into the remaining trench. Planarization and/or etching can be carried out as needed for subsequent processing. Thus, a methodology for filling high aspect ratio vias using a dual metal process is provided. Note, however, the first and second fill metals may be the same.

Abstract: Techniques are disclosed for providing a decoupled via fill. Given a via trench, a first barrier layer is conformally deposited onto the bottom and sidewalls of the trench. A first metal fill is blanket deposited into the trench. The non-selective deposition is subsequently recessed so that only a portion of the trench is filled with the first metal. The previously deposited first barrier layer is removed along with the first metal, thereby re-exposing the upper sidewalls of the trench. A second barrier layer is conformally deposited onto the top of the first metal and the now re-exposed trench sidewalls. A second metal fill is blanket deposited into the remaining trench. Planarization and/or etching can be carried out as needed for subsequent processing. Thus, a methodology for filling high aspect ratio vias using a dual metal process is provided. Note, however, the first and second fill metals may be the same.

Abstract: Methods and architectures for IC interconnect trenches, and trench plugs that define separations between two adjacent trench ends. Plugs and trenches may be defined through a multiple patterning process. An upper grating pattern may be summed with a plug keep pattern into a pattern accumulation layer. The pattern accumulation layer may be employed to define plug masks. A lower grating pattern may then be summed with the plug masks to define a pattern in trench ILD material, which can then be backfilled with interconnect metallization. As such, a complex damascene interconnect structure can be fabricated at the scaled-down geometries achievable with pitch-splitting techniques. In some embodiments, the trenches are located at spaces between first spacer masks defined in a patterning process associated with the first grating pattern while the plug masks are located based on a tone-inversion of second spacer masks associated with the second grating pattern.

Abstract: An embodiment includes an apparatus comprising: a metal layer comprising a plurality of interconnect lines on a plurality of vias; an additional metal layer comprising first, second, and third interconnect lines on first, second, and third vias; the first and third vias coupling the first and third interconnect lines to two of the plurality of interconnect lines; a lateral interconnect, included entirely within the additional metal layer, directly connected to each of the first, second, and third interconnect lines; and an insulator layer included entirely between two sidewalls of the second via. Other embodiments are described herein.

Abstract: Techniques are disclosed for forming a logic device including integrated spin-transfer torque magnetoresistive random-access memory (STT-MRAM). In accordance with some embodiments, one or more magnetic tunnel junction (MTJ) devices may be formed within a given back-end-of-line (BEOL) interconnect layer of a host logic device. A given MTJ device may be formed, in accordance with some embodiments, over an electrically conductive layer configured to serve as a pedestal layer for the MTJ's constituent magnetic and insulator layers. In accordance with some embodiments, one or more conformal spacer layers may be formed over sidewalls of a given MTJ device and attendant pedestal layer, providing protection from oxidation and corrosion. A given MTJ device may be electrically coupled with an underlying interconnect or other electrically conductive feature, for example, by another intervening electrically conductive layer configured to serve as a thin via, in accordance with some embodiments.

Abstract: Techniques are disclosed for providing a decoupled via fill. Given a via trench, a first barrier layer is conformally deposited onto the bottom and sidewalls of the trench. A first metal fill is blanket deposited into the trench. The non-selective deposition is subsequently recessed so that only a portion of the trench is filled with the first metal. The previously deposited first barrier layer is removed along with the first metal, thereby re-exposing the upper sidewalls of the trench. A second barrier layer is conformally deposited onto the top of the first metal and the now re-exposed trench sidewalls. A second metal fill is blanket deposited into the remaining trench. Planarization and/or etching can be carried out as needed for subsequent processing. Thus, a methodology for filling high aspect ratio vias using a dual metal process is provided. Note, however, the first and second fill metals may be the same.