Abstract: Each gate structure formed on the substrate includes a gate dielectric, a gate conductor, a first etch stop layer, and a gate cap dielectric. A second etch stop layer is formed over the gate structures, gate spacers, and source and drain regions. A first contact-level dielectric layer and a second contact-level dielectric layer are formed over the second etch stop layer. Gate contact via holes extending at least to the top surface of the gate cap dielectrics are formed. Source/drain contact via holes extending to the interface between the first and second contact-level dielectric layers are subsequently formed. The various contact via holes are vertically extended by simultaneously etching exposed gate cap dielectrics and exposed portions of the first contact-level dielectric layer, then by simultaneously etching the first and second etch stop layers. Source/drain contact vias self-aligned to the outer surfaces gate spacers are thereby formed.

Abstract: Embodiments of the present invention provide a structure. The structure includes a plurality of field-effect-transistors having gate stacks formed on top of a semiconductor substrate, the gate stacks having spacers formed at sidewalls thereof; and one or more conductive contacts formed directly on top of the semiconductor substrate and interconnecting at least one source/drain of one of the plurality of field-effect-transistors to at least one source/drain of another one of the plurality of field-effect-transistors, wherein the one or more conductive contacts is part of a low-profile local interconnect that has a height lower than a height of the gate stacks.

Abstract: Fin structures and methods of manufacturing fin structures using a dual-material sidewall image transfer mask to enable patterning of sub-lithographic features is disclosed. The method of forming a plurality of fins includes forming a first set of fins having a first pitch. The method further includes forming an adjacent fin to the first set of fins. The adjacent fin and a nearest fin of the first set of fins have a second pitch larger than the first pitch. The first set of fins and the adjacent fin are sub-lithographic features formed using a sidewall image transfer process.

Abstract: A metal layer is deposited on a planar surface on which top surfaces of underlying metal vias are exposed. The metal layer is patterned to form at least one metal block, which has a horizontal cross-sectional area of a metal line to be formed and at least one overlying metal via to be formed. Each upper portion of underlying metal vias is recessed outside of the area of a metal block located directly above. The upper portion of the at least one metal block is lithographically patterned to form an integrated line and via structure including a metal line having a substantially constant width and at least one overlying metal via having the same substantially constant width and borderlessly aligned to the metal line. An overlying-level dielectric material layer is deposited and planarized so that top surface(s) of the at least one overlying metal via is/are exposed.

Abstract: A finFET structure includes a semiconductor fin located over a substrate. A gate electrode is located traversing the semiconductor fin. The gate electrode has a spacer layer located adjoining a sidewall thereof. The spacer layer does not cover completely a sidewall of the semiconductor fin. The gate electrode and the spacer layer may be formed using a vapor deposition method that provides for selective deposition upon a sidewall of a mandrel layer but not upon an adjoining surface of the substrate, so that the spacer layer does not cover completely the sidewall of the semiconductor fin. Other microelectronic structures may be fabricated using the lateral growth methodology.

Abstract: Fin-defining spacers are formed on an array of mandrel structure. Mask material portions can be directionally deposited on fin-defining spacers located on one side of each mandrel structure, while not deposited on the other side. A photoresist layer is subsequently applied and patterned to form an opening, of which the overlay tolerance increases by a pitch of fin-defining spacers due to the mask material portions. Alternately, a conformal silicon oxide layer can be deposited on fin-defining spacers and structure-damaging ion implantation is performed only on fin-defining spacers located on one side of each mandrel structure. A photoresist layer is subsequently applied and patterned to form an opening, from which a damaged silicon oxide portion and an underlying fin-defining spacer are removed, while undamaged silicon oxide portions are not removed. An array of semiconductor fins including a vacancy can be formed by transferring the pattern into a semiconductor layer.

Abstract: Embodiments of the present invention provide an array of fin-type transistors formed on top of an oxide layer. At least a first and a second of the fin-type transistors have their respective source and drain contacts being formed inside the oxide layer, with one of the contacts of the first fin-type transistor being conductively connected to one of the contacts of the second fin-type transistor by an epitaxial silicon layer, wherein the epitaxial silicon layer is formed on top of a first and a second fin of the first and second fin-type transistors respectively.

Abstract: A method is provided that includes first etching a substrate according to a first mask. The first etching forms a first etch feature in the substrate to a first depth. The first etching also forms a sliver opening in the substrate. The sliver opening may then be filled with a fill material. A second mask may be formed by removing a portion of the first mask. The substrate exposed by the second mask may be etched with a second etch, in which the second etching is selective to the fill material. The second etching extends the first etch feature to a second depth that is greater than the first depth, and the second etch forms a second etch feature. The first etch feature and the second etch feature may then be filled with a conductive metal.

Abstract: A method of forming a semiconductor structure includes forming a sacrificial conductive material layer. The method also includes forming a trench in the sacrificial conductive material layer. The method further includes forming a conductive feature in the trench. The method additionally includes removing the sacrificial conductive material layer selective to the conductive feature. The method also includes forming an insulating layer around the conductive feature to embed the conductive feature in the insulating layer.

Abstract: A size-filtered metal interconnect structure allows formation of metal structures having different compositions. Trenches having different widths are formed in a dielectric material layer. A blocking material layer is conformally deposited to completely fill trenches having a width less than a threshold width. An isotropic etch is performed to remove the blocking material layer in wide trenches, i.e., trenches having a width greater than the threshold width, while narrow trenches, i.e., trenches having a width less than the threshold width, remain plugged with remaining portions of the blocking material layer. The wide trenches are filled and planarized with a first metal to form first metal structures having a width greater than the critical width. The remaining portions of the blocking material layer are removed to form cavities, which are filled with a second metal to form second metal structures having a width less than the critical width.

Abstract: After formation of raised source and drain regions, a conformal dielectric material liner is deposited within recessed regions formed by removal of shallow trench isolation structures and underlying portions of a buried insulator layer in a semiconductor-on-insulator (SOI) substrate. A dielectric material that is different from the material of the conformal dielectric material liner is subsequently deposited and planarized to form a planarized dielectric material layer. The planarized dielectric material layer is recessed selective to the conformal dielectric material liner to form dielectric fill portions that fill the recessed regions. Horizontal portions of the conformal dielectric material liner are removed by an anisotropic etch, while remaining portions of the conformal dielectric material liner form an outer gate spacer. At least one contact-level dielectric layer is deposited. Contact via structures electrically isolated from a handle substrate can be formed within the contact via holes.

Abstract: The profile of a via can be controlled by forming a profile control liner within each via opening that is formed into a dielectric material prior to forming a line opening within the dielectric material. The presence of the profile control liner within each via opening during the formation of the line opening prevents rounding of the corners of a dielectric material portion that is present beneath the line opening and adjacent the via opening.

Abstract: After formation of raised source and drain regions, a conformal dielectric material liner is deposited within recessed regions formed by removal of shallow trench isolation structures and underlying portions of a buried insulator layer in a semiconductor-on-insulator (SOI) substrate. A dielectric material that is different from the material of the conformal dielectric material liner is subsequently deposited and planarized to form a planarized dielectric material layer. The planarized dielectric material layer is recessed selective to the conformal dielectric material liner to form dielectric fill portions that fill the recessed regions. Horizontal portions of the conformal dielectric material liner are removed by an anisotropic etch, while remaining portions of the conformal dielectric material liner form an outer gate spacer. At least one contact-level dielectric layer is deposited. Contact via structures electrically isolated from a handle substrate can be formed within the contact via holes.

Abstract: In a replacement gate scheme, after formation of a gate dielectric layer, a work function material layer completely fills a narrow gate trench, while not filling a wide gate trench. A dielectric material layer is deposited and planarized over the work function material layer, and is subsequently recessed to form a dielectric material portion overlying a horizontal portion of the work function material layer within the wide gate trench. The work function material layer is recessed employing the dielectric material portion as a part of an etch mask to form work function material portions. A conductive material is deposited and planarized to form gate conductor portions, and a dielectric material is deposited and planarized to form gate cap dielectrics.

Abstract: A method is provided for fabricating a transistor. A replacement gate stack is formed on a semiconductor layer, a gate spacer is formed, and a dielectric layer is formed. The dummy gate stack is removed to form a cavity. A gate dielectric and a work function metal layer are formed in the cavity. The cavity is filled with a gate conductor. One and only one of the gate conductor and the work function metal layer are selectively recessed. An oxide film is formed in the recess such that its upper surface is co-planar with the upper surface of the dielectric layer. The oxide film is used to selectively grow an oxide cap. An interlayer dielectric is formed and etched to form a cavity for a source/drain contact. A source/drain contact is formed in the contact cavity, with a portion of the source/drain contact being located directly on the oxide cap.

Abstract: A high programming efficiency electrical fuse is provided utilizing a dual damascene structure located atop a metal layer. The dual damascene structure includes a patterned dielectric material having a line opening located above and connected to an underlying via opening. The via opening is located atop and is connected to the metal layer. The dual damascene structure also includes a conductive feature within the line opening and the via opening. Dielectric spacers are also present within the line opening and the via opening. The dielectric spacers are present on vertical sidewalls of the patterned dielectric material and separate the conductive feature from the patterned dielectric material. The presence of the dielectric spacers within the line opening and the via opening reduces the area in which the conductive feature is formed. As such, a high programming efficiency electrical fuse is provided in which space is saved.

Abstract: A stack of a first metal line and a first dielectric cap material portion is formed within a line trench of first dielectric material layer. A second dielectric material layer is formed thereafter. A line trench extending between the top surface and the bottom surface of the second dielectric material layer is patterned. A photoresist layer is applied over the second dielectric material layer and patterned with a via pattern. An underlying portion of the first dielectric cap material is removed by an etch selective to the dielectric materials of the first and second dielectric material layer to form a via cavity that is laterally confined along the widthwise direction of the line trench and along the widthwise direction of the first metal line. A dual damascene line and via structure is formed, which includes a via structure that is laterally confined along two independent horizontal directions.

Abstract: A hybrid interconnect structure containing copper regions that have different impurities levels within a same opening is provided. In one embodiment, the interconnect structure includes a patterned dielectric material having at least one opening located therein. A dual material liner is located at least on sidewalls of the patterned dielectric material within the at least one opening. The structure further includes a first copper region having a first impurity level located within a bottom region of the at least one opening and a second copper region having a second impurity level located within a top region of the at least one opening and atop the first copper region. In accordance with the present disclosure, the first impurity level of the first copper region is different from the second impurity level of the second copper region.

Abstract: Disclosed is a semiconductor structure which includes a semiconductor substrate and a wiring layer on the semiconductor substrate. The wiring layer includes a plurality of fin-like structures comprising a first metal; a first layer of a second metal on each of the plurality of fin-like structures wherein the first metal is different from the second metal, the first layer of the second metal having a height less than each of the plurality of fin-like structures; and an interlayer dielectric (ILD) covering the plurality of fin-like structures and the first layer of the second metal except for exposed edges of the plurality of fin-like structures at predetermined locations, and at locations other than the predetermined locations, the height of the plurality of fin-like structures has been reduced so as to be covered by the ILD.

Abstract: After formation of line openings in a hard mask layer, hard mask level spacers are formed on sidewalls of the hard mask layer. A photoresist is applied and patterned to form a via pattern including a via opening. The overlay tolerance for printing the via pattern is increased by the lateral thickness of the hard mask level spacers. A portion of a dielectric material layer is patterned to form a via cavity pattern by an etch that employs the hard mask layer and the hard mask level spacers as etch masks. The hard mask level spacers are subsequently removed, and the pattern of the line is subsequently transferred into an upper portion of the dielectric material layer, while the via cavity pattern is transferred to a lower portion of the dielectric material layer.