Abstract: A method for reducing series resistance for transistors includes forming a conductive gate over and insulated from a semiconductor substrate, forming source and/or drain extension regions within the substrate and adjacent to respective source and/or drain regions, and forming source and/or drain regions within the substrate. The source and/or drain extension regions are formed from a material alloyed with a first dopant and a second dopant, the first dopant configured to increase a lattice structure of the material forming the source and/or drain extension regions.

Abstract: A method of forming a semiconductor device that includes forming a vertically orientated channel in a semiconductor fin structure that is present on a supporting substrate; and depositing a doped amorphous semiconductor material on an upper surface of the semiconductor fin structure that is opposite a base surface of the semiconductor fin structure that is in contact with the supporting substrate. The method further includes recrystallizing the doped amorphous semiconductor material with an anneal duration for substantially a millisecond duration or less to provide a doped polycrystalline source and/or drain region at the upper surface of the semiconductor fin structure.

Abstract: Techniques for forming Ga-doped source drain contacts in Ge-based transistors are provided. In one aspect, a method for forming Ga-doped source and drain contacts includes the steps of: depositing a dielectric over a transistor; depositing a dielectric over the transistor; forming contact trenches in the dielectric over, and extending down to, source and drain regions of the transistor; depositing an epitaxial material into the contact trenches; implanting gallium ions into the epitaxial material to form an amorphous gallium-doped layer; and annealing the amorphous gallium-doped layer under conditions sufficient to form a crystalline gallium-doped layer having a homogenous gallium concentration of greater than about 5×1020 at./cm3. Transistor devices are also provided utilizing the present Ga-doped source and drain contacts.

Abstract: Described herein is a semiconductor structure and method of manufacture. The semiconductor structure includes a plurality of semiconductor fins on a substrate and a plurality of raised active regions, wherein each raised active region is located on sidewalls of a corresponding semiconductor fin among said plurality of semiconductor fins. The raised active regions are laterally spaced from any other of the raised active regions. Each raised active region comprises angled sidewall surfaces that are not parallel or perpendicular to a topmost horizontal surface of said substrate. The raised active regions are silicon germanium (SiGe). The semiconductor structure includes a metal semiconductor alloy region contacting at least said angled sidewall surfaces of at least two adjacent raised active regions. The semiconductor alloy region includes a material selected from the group consisting of nickel silicide, nickel-platinum silicide and cobalt silicide.

Abstract: A semiconductor structure is provided in which gallium-doped sacrificial epitaxial or polycrystalline germanium layer is formed on a silicon germanium substrate having a high percentage of germanium followed by annealing to diffuse the gallium into the silicon germanium substrate. The germanium layer is selectively removed to expose the surface of a gallium-doped silicon germanium region within the silicon germanium substrate. The process has application to the formation of electrically conductive regions within integrated circuits such as source/drain regions and junctions without the introduction of carbon into such regions.

Abstract: A technique relates to fabricating a pFET device and nFET device. A contact trench is formed through an inter-level dielectric layer (ILD) and a spacer layer. The ILD is formed over the spacer layer. The contact trench exposes a p-type source/drain region of the pFET and exposes an n-type source/drain region of the NFET. A gate stack is included within the spacer layer. A p-type alloyed layer is formed on top of the p-type source/drain region in the pFET and on top of the n-type source/drain region of the nFET. The p-type alloyed layer on top of the n-type source/drain region of the nFET is converted into a metallic alloyed layer. A metallic liner layer is formed in the contact trench such that the metallic liner layer is on top of the p-type alloyed layer of the pFET and on top of the metallic alloyed layer of the nFET.

Abstract: A technique relates to fabricating a semiconductor device. A contact trench is formed in an inter-level dielectric layer. The contact trench creates an exposed portion of a semiconductor substrate through the inter-level dielectric layer. A gate stack is on the semiconductor substrate, and the inter-level dielectric layer is adjacent to the gate stack and the semiconductor substrate. A source/drain region is formed in the contact trench such that the source/drain region is on the exposed portion of the semiconductor substrate. Tin is introduced in the source/drain region to form an alloyed layer on top of the source/drain region, and the alloyed layer includes the tin and a source/drain material of the source/drain region. A trench layer is formed in the contact trench such that the trench layer is on top of the alloyed layer. A metallic liner layer is formed on the trench layer and the inter-level dielectric layer.

Abstract: An EUV lithographic structure and methods according to embodiments of the invention includes an EUV photosensitive resist layer disposed directly on an oxide hardmask layer, wherein the oxide hardmask layer is doped with dopant ions to form a doped oxide hardmask layer so as to improve adhesion between the EUV lithographic structure and the oxide hardmask. The EUV lithographic structure is free of a separate adhesion layer.

Abstract: Techniques for forming a metastable phosphorous P-doped silicon Si source drain contacts are provided. In one aspect, a method for forming n-type source and drain contacts includes the steps of: forming a transistor on a substrate; depositing a dielectric over the transistor; forming contact trenches in the dielectric that extend down to source and drain regions of the transistor; forming an epitaxial material in the contact trenches on the source and drain regions; implanting P into the epitaxial material to form an amorphous P-doped layer; and annealing the amorphous P-doped layer under conditions sufficient to form a crystalline P-doped layer having a homogenous phosphorous concentration that is greater than about 1.5×1021 atoms per cubic centimeter (at./cm3). Transistor devices are also provided utilizing the present P-doped Si source and drain contacts.

Abstract: A technique relates to fabricating a pFET device and nFET device. A contact trench is formed through an inter-level dielectric layer (ILD) and a spacer layer. The ILD is formed over the spacer layer. The contact trench exposes a p-type source/drain region of the pFET and exposes an n-type source/drain region of the NFET. A gate stack is included within the spacer layer. A p-type alloyed layer is formed on top of the p-type source/drain region in the pFET and on top of the n-type source/drain region of the nFET. The p-type alloyed layer on top of the n-type source/drain region of the nFET is converted into a metallic alloyed layer. A metallic liner layer is formed in the contact trench such that the metallic liner layer is on top of the p-type alloyed layer of the pFET and on top of the metallic alloyed layer of the nFET.

Abstract: A method for reducing series resistance for transistors includes forming a conductive gate over and insulated from a semiconductor substrate, forming source and/or drain extension regions within the substrate and adjacent to respective source and/or drain regions, and forming source and/or drain regions within the substrate. The source and/or drain extension regions are formed from a material alloyed with a first dopant and a second dopant, the first dopant configured to increase a lattice structure of the material forming the source and/or drain extension regions.

Abstract: A method of forming a spacer for a vertical transistor is provided. The method includes forming a fin structure on a substrate, depositing a first spacer on exposed surfaces of the substrate to define gaps between the first spacer and the fin structure and depositing a second spacer on the exposed surfaces of the substrate in at least the gaps.

Abstract: The capacitance between gate structures and source/drain contacts of FinFET devices is reduced by the incorporation of inner spacers in the top portions of the gate structures. A replacement metal gate process used in the fabrication of such devices includes formation of the inner spacers following partial removal of dummy gate material. The remaining dummy gate material is then removed and replaced with gate dielectric and metal gate material.

Abstract: A semiconductor structure is provided that includes a bulk semiconductor substrate of a first semiconductor material. The structure further includes a plurality of fin pedestal structures of a second semiconductor material located on the bulk semiconductor substrate of the first semiconductor material, wherein the second semiconductor material is different from the first semiconductor material. In accordance with the present application, each fin pedestal structure includes a pair of spaced apart semiconductor fins of the second semiconductor material.

Abstract: A semiconductor material layer is deposited on a p-type source/drain region of a p-type transistor device and an n-type source/drain region of an n-type transistor device. The p-type device transistor device and the n-type transistor device are formed on a substrate of a semiconductor device. The semiconductor device includes a trench formed through an inter-level dielectric layer. The inter-level dielectric layer is formed over the n-type transistor device and the p-type transistor device. The trench exposes the p-type source/drain region of the p-type transistor device and the n-type source/drain region of the n-type transistor device. An element is implanted in the semiconductor material layer to form an amorphous layer on p-type source drain region and the n-type source/drain region. The amorphous layer is annealed to form a first metastable alloy layer upon the p-type source/drain region and a second metastable alloy layer upon the n-type source/drain region.

Abstract: A technique relates to fabricating a semiconductor device. A contact trench is formed in an inter-level dielectric layer. The contact trench creates an exposed portion of a semiconductor substrate through the inter-level dielectric layer. A gate stack is on the semiconductor substrate, and the inter-level dielectric layer is adjacent to the gate stack and the semiconductor substrate. A source/drain region is formed in the contact trench such that the source/drain region is on the exposed portion of the semiconductor substrate. Tin is introduced in the source/drain region to form an alloyed layer on top of the source/drain region, and the alloyed layer includes the tin and a source/drain material of the source/drain region. A trench layer is formed in the contact trench such that the trench layer is on top of the alloyed layer. A metallic liner layer is formed on the trench layer and the inter-level dielectric layer.

Abstract: A semiconductor structure is provided that includes a bulk semiconductor substrate of a first semiconductor material. The structure further includes a plurality of fin pedestal structures of a second semiconductor material located on the bulk semiconductor substrate of the first semiconductor material, wherein the second semiconductor material is different from the first semiconductor material. In accordance with the present application, each fin pedestal structure includes a pair of spaced apart semiconductor fins of the second semiconductor material.

Abstract: An nFET vertical transistor is provided in which a p-doped top source/drain structure is formed in contact with an n-doped semiconductor region that is present on a topmost surface of a vertical nFET channel. The p-doped top source/drain structure is formed utilizing a low temperature (550° C. or less) epitaxial growth process.

Abstract: A semiconductor material layer is deposited on a p-type source/drain region of a p-type transistor device and an n-type source/drain region of an n-type transistor device. The p-type device transistor device and the n-type transistor device are formed on a substrate of a semiconductor device. The semiconductor device includes a trench formed through an inter-level dielectric layer. The inter-level dielectric layer is formed over the n-type transistor device and the p-type transistor device. The trench exposes the p-type source/drain region of the p-type transistor device and the n-type source/drain region of the n-type transistor device. An element is implanted in the semiconductor material layer to form an amorphous layer on p-type source drain region and the n-type source/drain region. The amorphous layer is annealed to form a first metastable alloy layer upon the p-type source/drain region and a second metastable alloy layer upon the n-type source/drain region.

Abstract: An nFET vertical transistor is provided in which a p-doped top source/drain structure is formed in contact with an n-doped semiconductor region that is present on a topmost surface of a vertical nFET channel. The p-doped top source/drain structure is formed utilizing a low temperature (550° C. or less) epitaxial growth process.