Abstract: An electrical device including at least one contact surface and an interlevel dielectric layer present atop the electrical device, wherein the interlevel dielectric layer includes at least one trench to the at least one contact surface of the electrical device. A conformal titanium liner is present on the sidewalls of the trench and is in direct contact with the at least one contact surface. The conformal titanium liner may be composed of 100 wt. % titanium, and may have a thickness ranging from 10 ? to 100 ?.

Abstract: A method of forming a contact to a semiconductor device that includes forming a vertically orientated channel region on semiconductor material layer of a substrate; and forming a first source/drain region in the semiconductor material layer. The method may continue with forming a metal semiconductor alloy contact on the first source/drain region extending along a horizontally orientated upper surface of the first source/drain region that is substantially perpendicular to the vertically orientated channel region, wherein the metal semiconductor alloy contact extends substantially to an interface with the vertically orientated channel region. Thereafter, a gate structure is formed on the vertically orientated channel region, and a second source/drain region is formed on the vertically orientated channel region.

Abstract: A method and apparatus for forming a semiconductor structure is provided. The semiconductor structure comprises a stacked fin structure formed on a surface of a first insulator layer. The stacked fin structure comprises a first doped semiconductor fin portion and a second doped semiconductor fin portion. The anti-fuse structure further comprises a first highly doped diamond shaped epitaxial structure grown about the first semiconductor fin portion and a second diamond shaped highly doped epitaxial structure grown about the second semiconductor fin portion. The first highly doped epitaxial structure has a lower-most apex overlying and aligned with an upper-most apex of the second highly doped epitaxial structure. The lower-most apex is separated from the upper-most apex by a gap. A second insulating layer formed about the first highly-doped epitaxial structure and the second highly-doped epitaxial structure, wherein the second insulator layer fills the gap.

Abstract: A method of forming source/drain contact structures that exhibit low contact resistance and improved electromigration properties is provided. After forming a first contact conductor portion composed of a metal having a high resistance to electromigration, such as, for example, tungsten, at a bottom portion of source/drain contact trench to form direct contact with a source/drain region of a field effect transistor, a second contact conductor portion composed of a highly conductive metal, such as, for example, copper or a copper alloy, is formed over the first contact conductor portion.

Abstract: A buried metal-insulator-metal (MIM) capacitor with landing pads is formed between first and second semiconductor substrates. The landing pads provide increased area for contacting which may decrease the contact resistors of the capacitor. The area of the buried MIM capacitor can be varied to provide a tailored capacitance. The buried MIM capacitor is thermally stable since the MIM capacitor includes refractory metal or metal alloy layers as the capacitor plates.

Abstract: Embedded resistors which have tunable resistive values located between interconnect levels are provided. The embedded resistors have a pillar structure, i.e., they have a height that is greater than their width, thus they occupy less real estate as compared with conventional planar resistors that are typically employed in BEOL technology.

Abstract: A structure is provided that includes a lower interconnect level that includes a first interconnect dielectric material layer having an opening that contains a first bimetallization interconnect structure. An upper interconnect level is located above the lower interconnect level. The upper interconnect level includes a second interconnect dielectric material layer having a combined via/line opening, wherein the line portion of the combined via/line opening contains a second bimetallization interconnect structure.

Abstract: A semiconductor structure is provided in which metal semiconductor alloy pillars are formed at least partially within the sidewall surfaces of each semiconductor fin that extends from a surface of a substrate. These pillars are fuses (i.e., FinFET fuses) that are formed at a very tight pitch dimensions. The pillars can be trimmed after forming FinFET devices. The present application provides a method for forming on-chip FinFET fuses easily by choice of the metal semiconductor alloy, the amount of pillar trim, the number of contacted pillars and to a lower design degree the height of each pillar.

Abstract: A method of forming a contact to a semiconductor device that includes forming a vertically orientated channel region on semiconductor material layer of a substrate; and forming a first source/drain region in the semiconductor material layer. The method may continue with forming a metal semiconductor alloy contact on the first source/drain region extending along a horizontally orientated upper surface of the first source/drain region that is substantially perpendicular to the vertically orientated channel region, wherein the metal semiconductor alloy contact extends substantially to an interface with the vertically orientated channel region. Thereafter, a gate structure is formed on the vertically orientated channel region, and a second source/drain region is formed on the vertically orientated channel region.

Abstract: Semiconductor structures containing FinFET anti-fuses with reduced breakdown voltage are provided which can be readily integrated with high performance FinFETs. The anti-fuse includes at least one metal structure having a faceted sidewall. The sharp corner of the faceted sidewall of the at least one metal structure causes an electric field concentration, thus reducing the breakdown voltage of the anti-fuse.

Abstract: A cobalt contact includes a dual silicide barrier layer. The barrier layer, which may be formed in situ, includes silicides of titanium and cobalt, and provides an effective adhesion layer between the cobalt contact and a conductive device region such as the source/drain junction of a semiconductor device, eliminating void formation during a metal anneal.

Abstract: An electrical device is provided that includes at least one contact surface and an interlevel dielectric layer present atop the electrical device. The interlevel dielectric layer may include at least one trench to the at least one contact surface of the electrical device. A liner of tantalum or tantalum nitride can be present on sidewalls of the trench structure and a base surface of the trench provided by the contact surface of the electrical device. A copper fill promoting liner that includes at least one ruthenium (Ru), rhodium (Rh), iridium (Ir), osmium (Os), molybdenum (Mo), and copper (Cu) may be in direct contact with the liner of tantalum or tantalum nitride. A copper containing metal that fills the at least one trench and is present directly on the copper fill promoting liner.

Abstract: Various methods and semiconductor structures for fabricating an FET device having Nickel atoms implanted in a silicide metal film on a source-drain contact region of the FET device thereby reducing resistance of the source-drain contact region of the FET device. An example fabrication method includes maskless blanket implantation of Nickel atoms across a semiconductor wafer. Nickel atoms can be implanted into silicide metal film of a source-drain contact region of nFET devices, pFET devices, or both, on a semiconductor wafer. Nickel atoms can be implanted into silicide metal film on a source-drain contact region of nFET devices and pFET devices. The silicide metal film on the source-drain contact region of the nFET device being a different material than the silicide metal film on the source-drain contact region of the pFET device.

Abstract: After forming a contact opening in a dielectric material layer located over a substrate, a metal liner layer comprising a nitride of an alloy and a metal contact layer comprising the alloy that provides the metal liner layer are deposited in-situ in the contact opening by sputter deposition in a single process and without an air break. Compositions of the metal liner layer and the metal contact layer can be changed by varying gas compositions employed in the sputtering process.

Abstract: At least one opening having a biconvex shape is formed into a dielectric material layer. A void-free metallization region (interconnect metallic region and/or metallic contact region) is provided to each of the openings. The void-free metallization region has the biconvex shape and exhibits a low wire resistance.

Abstract: A semiconductor structure is provided that includes a contact structure containing a gouged upper surface embedded in at least a middle-of-the-line (MOL) dielectric material, wherein the contact structure contacts an underlying doped semiconductor material structure. A first metallization structure containing a gouged upper surface is in contact with the gouged upper surface of the contact structure and embedded in a first interconnect dielectric material. A second metallization structure is in contact with the gouged upper surface of the first metallization structure and embedded at least within a second interconnect dielectric material.

Abstract: A structure is provided that includes a lower interconnect level that includes a first interconnect dielectric material layer having an opening that contains a first bimetallization interconnect structure. An upper interconnect level is located above the lower interconnect level. The upper interconnect level includes a second interconnect dielectric material layer having a combined via/line opening, wherein the line portion of the combined via/line opening contains a second bimetallization interconnect structure.

Abstract: After forming a contact opening in a dielectric material layer located over a substrate, a metal liner layer comprising a nitride of an alloy and a metal contact layer comprising the alloy that provides the metal liner layer are deposited in-situ in the contact opening by sputter deposition in a single process and without an air break. Compositions of the metal liner layer and the metal contact layer can be changed by varying gas compositions employed in the sputtering process.

Abstract: An electrical device including at least one contact surface and an interlevel dielectric layer present atop the electrical device, wherein the interlevel dielectric layer includes at least one trench to the at least one contact surface of the electrical device. A conformal titanium liner is present on the sidewalls of the trench and is in direct contact with the at least one contact surface. The conformal titanium liner may be composed of 100 wt. % titanium, and may have a thickness ranging from 10? to 100?.

Abstract: A semiconductor structure is provided that includes a first interconnect dielectric layer containing a first interconnect metal structure embedded therein. A second interconnect dielectric layer containing a second interconnect metal structure embedded therein is located atop the first interconnect dielectric layer. A metallic blocking layer is present that separates a surface of the second interconnect metal structure from a surface of the first interconnect metal structure. The metallic blocking layer has a lower resistivity than the first and second interconnect metal structures. The metallic blocking layer prevents electromigration of metallic ions from the first and second interconnect metal structure.