Abstract: A conductive microstud is formed in a recess of an insulator layer formed on the substrate. A bottom pedestal is formed on a top surface of the microstud. The material used for the bottom pedestal has a lower electrochemical voltage than a material used for the microstud. A top pedestal is formed on a top surface of the bottom pedestal. The top surface of at least one of the bottom pedestal and top pedestal is planarized. A conductive layer is formed on a top surface of the top pedestal. Next, a conical structure is formed. The conical structure is comprised of at least the conductive layer and a top portion of the top pedestal.

Abstract: Interconnect structures and processes of fabricating the interconnect structures generally includes partially or completely cobalt filled openings. The cobalt metal is conformally deposited onto a noble metal layer and thermally annealed to reflow the cobalt metal and partially or completely fill the openings.

Abstract: A method of forming a semiconductor device having a vertical metal line interconnect (via) fully aligned to a first direction of a first interconnect layer and a second direction of a second interconnect layer in a selective recess region by forming a plurality of metal lines in a first dielectric layer; and recessing in a recess region first portions of the plurality of metal lines such that top surfaces of the first portions of the plurality of metal lines are below a top surface of the first dielectric layer; wherein a non-recess region includes second portions of the plurality of metal lines that are outside the recess region.

Abstract: Embodiments of the invention are directed to a method of forming a memory element pillar. The method includes forming memory element stack layers, forming a conductive cap layer over the memory element stack layers, forming a conductive seal layer over the cap layer, and forming a conductive etch stop layer over the conductive seal layer, wherein the conductive etch stop layer comprises a substantially planar surface. A hardmask is formed over the substantially planar surface of the conductive etch stop layer, wherein the hardmask defines dimensions of the memory element pillar.

Abstract: A method for fabricating a semiconductor device includes forming one or more encapsulation spacers each about respective ones of one more memory pillar elements to have a geometry, including forming each encapsulation spacer to have a footing of at least about twice a critical dimension of its corresponding pillar, and depositing dielectric material on the one or more memory pillar elements and the one or more encapsulation spacers to form an interlayer dielectric free of voids based on the geometry.

Abstract: An electrical device structure including a magnetic tunnel junction structure having a first tunnel junction dielectric layer positioned between a free magnetization layer and a fixed magnetization layer. A magnetization enhancement stack present on the magnetic tunnel junction structure. The magnetization enhancement stack includes a second tunnel junction layer that is in contact with the free magnetization layer of the magnetic tunnel junction structure, a metal contact layer present on the second tunnel junction layer, and a metal electrode layer present on the metal contact layer. A metallic ring on a sidewall of the magnetic enhancement stack, wherein a base of the metallic ring may be in contact with the free magnetization layer of the magnetic tunnel junction structure.

Abstract: A structure and a method for fabricating a bottom electrode for an integrated circuit device are described. A first dielectric layer is provided over a substrate and the first dielectric layer has a recess. A bottom electrode is formed over the recess. The bottom electrode consists of a microstud layer disposed completely within the recess of the dielectric and conforming to the recess, a bottom pedestal disposed on a top surface of the microstud and a top pedestal on a top surface of the bottom pedestal. The material used for the bottom pedestal has a lower electrochemical voltage than a material used for the microstud. A conductive element of the integrated circuit device is formed on a top surface of the bottom electrode. A first portion of the bottom electrode is disposed in and conforms to the recess. A second portion of the bottom electrode and the conductive element are conical sections.

Abstract: Replacement metal gate structures with improved chamfered workfunction metal and self-aligned contact and methods of manufacture are provided. The method includes forming a replacement metal gate structure in a dielectric material. The replacement metal gate structure is formed with a lower spacer and an upper spacer above the lower spacer. The upper spacer having material is different than material of the lower spacer. The method further includes forming a self-aligned contact adjacent to the replacement metal gate structure by patterning an opening within the dielectric material and filling the opening with contact material. The upper spacer prevents shorting with the contact material.

Abstract: Replacement metal gate structures with improved chamfered workfunction metal and self-aligned contact and methods of manufacture are provided. The method includes forming a replacement metal gate structure in a dielectric material. The replacement metal gate structure is formed with a lower spacer and an upper spacer above the lower spacer. The upper spacer having material is different than material of the lower spacer. The method further includes forming a self-aligned contact adjacent to the replacement metal gate structure by patterning an opening within the dielectric material and filling the opening with contact material. The upper spacer prevents shorting with the contact material.

Abstract: A method is presented for forming a semiconductor structure. The method includes forming gate contacts on a semiconductor substrate, forming trench silicide (TS) contacts on the semiconductor substrate, recessing the TS contacts to form a gap region, filling the gap region of the recessed TS contacts with a dielectric, selectively etching the gate contacts to form a first conducting layer, and selectively etching the TS contacts to form a second conducting layer.

Abstract: A vertical transistor includes a first source/drain region and a second source/drain region vertically disposed relative to the first source/drain region and coupled to the first source/drain region by a fin. A gate dielectric is formed on the fin, and a gate conductor is formed on the gate dielectric in a region of the fin. A shaped spacer is configured to cover a lower portion and sides of the second source/drain region to reduce parasitic capacitance between the gate conductor and the second source/drain region.

Abstract: Back end of line (BEOL) metallization structures and methods generally includes forming a landing pad on an interconnect structure. A multilayer structure including layers of metals and at least one insulating layer are provided on the structure and completely cover the landing pad. The landing pad is a metal-filled via and has a width dimension that is smaller than the multilayer structure, or the multilayer structure and the underlying metal conductor in the interconnect structure. The landing pad metal-filled via can have a width dimension that is sub-lithographic.

Abstract: Back end of line (BEOL) metallization structures and methods generally includes forming a landing pad on an interconnect structure. A multilayer structure including layers of metals and at least one insulating layer are provided on the structure and completely cover the landing pad. The landing pad is a metal-filled via and has a width dimension that is smaller than the multilayer structure, or the multilayer structure and the underlying metal conductor in the interconnect structure. The landing pad metal-filled via can have a width dimension that is sub-lithographic.

Abstract: An intermediate semiconductor device structure includes a first area including a memory stack area and a second area including an alignment mark area. The intermediate structure includes a metal interconnect arranged on a substrate in the first area and a first electrode layer arranged on the metal interconnect in the first area, and in the second area. The intermediate structure includes an alignment assisting marker arranged in the second area. The intermediate structure includes a dielectric layer and a second electrode layer arranged on the alignment assisting marker in the second area and on the metal interconnect in the first area. The intermediate structure includes a hard mask layer arranged on the second electrode area. The hard mask layer provides a raised area of topography over the alignment assisting marker. The intermediate structure includes a resist arranged on the hard mask layer in the first area.

Abstract: Replacement metal gate structures with improved chamfered workfunction metal and self-aligned contact and methods of manufacture are provided. The method includes forming a replacement metal gate structure in a dielectric material. The replacement metal gate structure is formed with a lower spacer and an upper spacer above the lower spacer. The upper spacer having material is different than material of the lower spacer. The method further includes forming a self-aligned contact adjacent to the replacement metal gate structure by patterning an opening within the dielectric material and filling the opening with contact material. The upper spacer prevents shorting with the contact material.

Abstract: A semiconductor structure, such as a strained FinFETs, includes a strain relief buffer (SRB) layer isolated and separated from a source and a drain by a spacer that may be simultaneously formed with a gate spacer upon the sidewalls of a gate structure. The spacer limits the source and drain from contacting the SRB layer thereby limiting source drain junction leakage. Further, the spacer limits source and drain punch through to the SRB layer underneath a channel. An etch may partially remove a SRB layer portion within a fin stack. The etch undercuts the source and drain forming a fin void without under cutting the channel. The spacer may be formed by depositing spacer material with the fin void.

Abstract: Replacement metal gate structures with improved chamfered workfunction metal and self-aligned contact and methods of manufacture are provided. The method includes forming a replacement metal gate structure in a dielectric material. The replacement metal gate structure is formed with a lower spacer and an upper spacer above the lower spacer. The upper spacer having material is different than material of the lower spacer. The method further includes forming a self-aligned contact adjacent to the replacement metal gate structure by patterning an opening within the dielectric material and filling the opening with contact material. The upper spacer prevents shorting with the contact material.

Abstract: A multipurpose semiconductor process chamber includes a vessel wall that encloses contiguous first and second volumes of the multipurpose chamber, and means for selectively effectively preventing ions moving across a plane that partitions the first volume from the second volume. For example, the means can include an electromagnet, or at least one permanent magnet, that is operable to impose and remove a magnetic field with field lines extending in the plane.

Abstract: Replacement metal gate structures with improved chamfered workfunction metal and self-aligned contact and methods of manufacture are provided. The method includes forming a replacement metal gate structure in a dielectric material. The replacement metal gate structure is formed with a lower spacer and an upper spacer above the lower spacer. The upper spacer having material is different than material of the lower spacer. The method further includes forming a self-aligned contact adjacent to the replacement metal gate structure by patterning an opening within the dielectric material and filling the opening with contact material. The upper spacer prevents shorting with the contact material.

Abstract: An integrated FinFET and deep trench capacitor structure and methods of manufacture are disclosed. The method includes forming at least one deep trench capacitor in a silicon on insulator (SOI) substrate. The method further includes simultaneously forming polysilicon fins from material of the at least one deep trench capacitor and SOI fins from the SOI substrate. The method further includes forming an insulator layer on the polysilicon fins. The method further includes forming gate structures over the SOI fins and the insulator layer on the polysilicon fins.