Abstract: A method for fabricating a semiconductor device includes accessing source/drain regions (S/D) in an n-type field effect transistor (NFET) region and in a p-type field effect transistor (PFET) region. First alloy elements are implanted in the S/D regions in the NFET region, and second alloy elements are implanted in the PFET region with the NFET region blocked. The first and second alloy elements form respective amorphized layers on the S/D regions in respective NFET and PFET regions. The amorphized layers are recrystallized to form metastable recrystallized interfaces using an epitaxy process wherein the metastable recrystallized interfaces formed in respective NFET and PFET regions exceed solubility of the first and second alloy elements in respective materials of the S/D regions in the NFET and PFET regions. Contacts to the metastable recrystallized layers of the S/D regions in the NFET and PFET regions are concurrently formed.

Abstract: A method for formation of multi-level contact structures with reduced contact resistance is provided. The contact resistance of the multi-level contact structures can be reduced by selectively removing portions of a contact liner layer that are formed along sidewalls and bottom portions of contact openings located in each contact level from the bottom portions of the contact openings.

Abstract: A low resistance middle-of-line interconnect structure is formed without liner layers. A contact metal layer is deposited on source/drain regions of field-effect transistors and directly on the surfaces of trenches within a dielectric layer using plasma enhancement. Contact metal fill is subsequently provided by thermal chemical vapor deposition. The use of low-resistivity metal contact materials such as ruthenium is facilitated by the process. The process further facilitates the formation of metal silicide regions on the source/drain regions.

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 middle-of-line interconnect structure including copper interconnects and integral copper alloy caps provides effective electromigration resistance. A metal cap layer is deposited on the top surfaces of the interconnects. A post-deposition anneal causes formation of the copper alloy caps from the interconnects and the metal cap layer. Selective removal of unalloyed metal cap layer material provides an interconnect structure free of metal residue on the dielectric material layer separating the interconnects.

Abstract: A reflow enhancement layer is formed in an opening prior to forming and reflowing a contact metal or metal alloy. The reflow enhancement layer facilitates the movement (i.e., flow) of the contact metal or metal alloy during a reflow anneal process such that a void-free metallization structure of the contact metal or metal alloy is provided.

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: Various methods and semiconductor structures for fabricating at least one FET device having textured gate-source-drain contacts of the FET device that reduce or eliminate variability in parasitic resistance between the contacts of the FET device. An example fabrication method includes epitaxially growing a source-drain contact region on an underlying semiconductor substrate of one of a pFET device or an nFET device. The method deposits a bottom film layer directly on the epitaxially grown source-drain contact region. A first anneal forms a textured bottom silicide film layer directly on the epitaxially grown source-drain contact region. A top metal film layer is deposited on the textured bottom silicide film layer. A second anneal forms a textured top metal silicide film layer. The method can be repeated on the other one of the pFET device or the nFET device.

Abstract: An antifuse is provided that is embedded in a semiconductor substrate. The antifuse has a large contact area, and a reduced breakdown voltage. After blowing the antifuse, the antifuse has a low resistance. The antifuse may have a single breakdown point or multiple breakdown points. The antifuse includes a metal or metal alloy structure that is separated from a doped semiconductor material portion of the semiconductor substrate by an antifuse dielectric material liner. The metal or metal alloy structure and the antifuse dielectric material liner have topmost surfaces that are coplanar with each other as well as being coplanar with a topmost surface of the semiconductor substrate.

Abstract: A method for fabricating a semiconductor device includes accessing source/drain regions (S/D) in an n-type field effect transistor (NFET) region and in a p-type field effect transistor (PFET) region. First alloy elements are implanted in the S/D regions in the NFET region, and second alloy elements are implanted in the PFET region with the NFET region blocked. The first and second alloy elements form respective amorphized layers on the S/D regions in respective NFET and PFET regions. The amorphized layers are recrystallized to form metastable recrystallized interfaces using an epitaxy process wherein the metastable recrystallized interfaces formed in respective NFET and PFET regions exceed solubility of the first and second alloy elements in respective materials of the S/D regions in the NFET and PFET regions. Contacts to the metastable recrystallized layers of the S/D regions in the NFET and PFET regions are concurrently formed.

Abstract: A low resistance middle-of-line interconnect structure is formed without liner layers. A contact metal layer is deposited on source/drain regions of field-effect transistors and directly on the surfaces of trenches within a dielectric layer using plasma enhancement. Contact metal fill is subsequently provided by thermal chemical vapor deposition. The use of low-resistivity metal contact materials such as ruthenium is facilitated by the process. The process further facilitates the formation of metal silicide regions on the source/drain regions.

Abstract: Devices and methods of fabricating integrated circuit devices via cobalt fill metallization are provided. A method includes, for instance, providing an intermediate semiconductor device having at least one trench, forming at least one layer of semiconductor material on the device, depositing a first cobalt (Co) layer on the second layer, and performing an anneal reflow process on the device. Also provided are intermediate semiconductor devices. An intermediate semiconductor device includes, for instance, at least one trench formed within the device, the trench having a bottom portion and sidewalls, at least one layer of semiconductor material disposed on the device, a first cobalt (Co) layer disposed on the at least one layer of semiconductor material, wherein the at least one layer of semiconductor material includes at least a first semiconductor material and a second semiconductor material.

Abstract: A semiconductor substrate includes lower source/drain (S/D) regions. A replacement metal gate (RMG) structure is arranged upon the semiconductor substrate between the lower S/D regions. Raised S/D regions are arranged upon the lower S/D regions adjacent to the RMG structure, respectively. The raised S/D regions may be recessed to form contact trenches. First self-aligned contacts are located upon the raised S/D regions within a first active area and second self-aligned contacts are located upon the recessed raised S/D regions in the second active area. The first and second self-aligned contacts allows for independent reduction of source drain contact resistances. The first self-aligned contacts may be MIS contacts or metal silicide contacts and the second self-aligned contacts may be metal-silicide contacts.

Abstract: A resistor structure composed of a metal liner is embedded within a MOL dielectric material and is located, at least in part, on a surface of a doped semiconductor material structure. The resistor structure is located on a same interconnect level of the semiconductor structure as a lower contact structure and both structures are embedded within the same MOL dielectric material. The metal liner that provides the resistor structure is composed of a metal or metal alloy having a higher resistivity than a metal or metal alloy that provides the contact metal of the lower contact structure.

Abstract: A method for forming a salicide includes epitaxially growing source/drain (S/D) regions on a semiconductor fin wherein the S/D regions include (111) facets in a diamond shape and the S/D regions on adjacent fins have separated diamond shapes. A metal is deposited on the (111) facets. A thermally stabilizing anneal process is performed to anneal the metal on the S/D regions to form a silicide on the (111) facets. A dielectric layer is formed over the S/D regions. The dielectric layer is opened up to expose the silicide and to form contact holes. Contacts to the silicide are formed in the contact holes.

Abstract: A method for forming a salicide includes epitaxially growing source/drain (S/D) regions on a semiconductor fin wherein the S/D regions include (111) facets in a diamond shape and the S/D regions on adjacent fins have separated diamond shapes. A metal is deposited on the (111) facets. A thermally stabilizing anneal process is performed to anneal the metal on the S/D regions to form a silicide on the (111) facets. A dielectric layer is formed over the S/D regions. The dielectric layer is opened up to expose the silicide and to form contact holes. Contacts to the silicide are formed in the contact holes.

Abstract: An antifuse device includes a gate structure formed on a substrate including first spacers formed in an upper portion and a conductive material formed in a lower portion below the first spacers. Two conductive regions are disposed adjacent to the gate structure and on opposite sides of the gate structure. A dielectric barrier is formed between the conductive material and each of the conductive regions such that a dual antifuse is formed across the dielectric barrier between the conductive material and the conductive regions on each side of the gate structure.

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 deep trench capacitor having a high capacity is formed into a deep trench having faceted sidewall surfaces. The deep trench is located in a bulk silicon substrate that contains an upper region of undoped silicon and a lower region of n-doped silicon. The lower region of the bulk silicon substrate includes alternating regions of n-doped silicon that have a first boron concentration (i.e., boron deficient regions), and regions of n-doped silicon that have a second boron concentration which is greater than the first boron concentration (i.e., boron rich regions).

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?.