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: During a fabrication of a semiconductor device, a recess is created in a substrate material disposed along a direction of a plane of fabrication. A layer of a removable material is formed in the recess. A bottom layer is formed above the layer of removable material. A vertical channel above the bottom layer is formed in a direction substantially orthogonal to the direction of the plane of fabrication. A gate is formed using a metal above the bottom layer and relative to the vertical channel. A tunnel is created under the bottom layer by removing the removable material from under the bottom layer such that the backside of the bottom layer forms a ceiling of the tunnel. The tunnel is filled using a conductive material such that the conductive material makes electrical contact with the backside of the bottom layer.

Abstract: Embodiments are directed to a method and resulting structures for a vertical field effect transistor (VFET) having a reduced bottom contact resistance. A multilayered bottom doped region having alternating doped layers and doped sacrificial layers is formed on a substrate. One or more cavities are formed by removing portions of the doped sacrificial layers. A bottom contact is formed over the multilayered bottom doped region. The bottom contact includes one or more conductive flanges that fill the cavities.

Abstract: During a fabrication of a semiconductor device, a recess is created in a substrate material disposed along a direction of a plane of fabrication. A layer of a removable material is formed in the recess. A bottom layer is formed above the layer of removable material. A vertical channel above the bottom layer is formed in a direction substantially orthogonal to the direction of the plane of fabrication. A gate is formed using a metal above the bottom layer and relative to the vertical channel. A tunnel is created under the bottom layer by removing the removable material from under the bottom layer such that the backside of the bottom layer forms a ceiling of the tunnel. The tunnel is filled using a conductive material such that the conductive material makes electrical contact with the backside of the bottom layer.

Abstract: A method of forming a semiconductor device that includes providing a vertically orientated channel region; and converting a portion of an exposed source/drain contact surface of the vertically orientated channel region into an amorphous crystalline structure. The amorphous crystalline structure is from the vertically orientated channel region. An in-situ doped extension region is epitaxially formed on an exposed surface of the vertically orientated channel region. A source/drain region is epitaxially formed on the in-situ doped extension region.

Abstract: During a fabrication of a semiconductor device, a recess is created in a substrate material disposed along a direction of a plane of fabrication. A layer of a removable material is formed in the recess. A bottom layer is formed above the layer of removable material. A vertical channel above the bottom layer is formed in a direction substantially orthogonal to the direction of the plane of fabrication. A gate is formed using a metal above the bottom layer and relative to the vertical channel. A tunnel is created under the bottom layer by removing the removable material from under the bottom layer such that the backside of the bottom layer forms a ceiling of the tunnel. The tunnel is filled using a conductive material such that the conductive material makes electrical contact with the backside of the bottom layer.

Abstract: The present invention relates generally to semiconductor devices and more particularly, to a structure and method of forming a fin using double trench epitaxy. The fin may be composed of a III-V semiconductor material and may be grown on a silicon, silicon germanium, or germanium substrate. A double trench aspect ratio trapping (ART) epitaxy method may trap crystalline defects within a first trench (i.e. a defective region) and may permit formation of a fin free of patterning defects in an upper trench (i.e. a fin mold). Crystalline defects within the defective region may be trapped via conventional aspect ratio trapping or three-sided aspect ratio trapping. Fin patterning defects may be avoided by utilizing a fin mold to grow an epitaxial fin and selectively removing dielectric material adjacent to a fin region.

Abstract: Relaxed silicon germanium fins are formed on a bulk silicon substrate through the lateral recrystallization of molten silicon germanium having high germanium content. Following formation of the silicon germanium fins, the silicon is selectively recessed. The resulting trenches are filled with electrically insulating material and then recessed down to the bottoms of the fins.

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: Low temperature epitaxial silicon deposition for forming the top source or drain regions of VTFET structures. The methods generally include epitaxially growing a silicon layer with a dopant at a temperature less 500° C. on a first surface and an additional surface to form a single crystalline silicon on the first surface and a polysilicon or amorphous silicon on the additional surface. The epitaxially grown silicon layer is then exposed to an etchant include HCl and germane at a temperature less than 500° C. for a period of time effective to selectively remove the polysilicon/amorphous silicon on the additional surface and form a germanium diffused region on and in an outer surface of the single crystalline silicon formed on the first surface.

Abstract: MIS capacitors are formed using a finned semiconductor structure. A highly doped region including the fins is formed within the structure and forms one plate of a MIS capacitor. A metal layer forms a second capacitor plate that is separated from the first plate by a high-k capacitor dielectric layer formed directly on the highly doped fins. Contacts are electrically connected to the capacitor plates. A highly doped implantation layer having a conductivity type opposite to that of the highly doped region provides electrical isolation within the structure.

Abstract: A semiconductor structure is provided that includes a plurality of high mobility semiconductor material (i.e., silicon germanium alloy of III-V compound semiconductors) fins located above and spaced apart from a bulk semiconductor substrate portion, wherein each of the high mobility semiconductor material fins has a lower faceted surface that is confined within a dielectric isolation structure.

Abstract: A method is presented for forming a semiconductor structure. The method includes forming a silicon (Si) channel for a first device, forming a first interfacial layer over the Si channel, forming a silicon-germanium (SiGe) channel for a second device, forming a second interfacial layer over the SiGe channel, and selectively removing germanium oxide (GeOX) from the second interfacial layer by applying a combination of hydrogen (H2) and hydrogen chloride (HCl). The second interfacial is silicon germanium oxide (SiGeOX) and removal of the GeOX results in formation of a pure silicon dioxide (SiO2) layer.

Abstract: A modified silicon substrate having a substantially defect-free strain relaxed buffer layer of SiGe is suitable for use as a foundation on which to construct a high performance CMOS FinFET device. The substantially defect-free SiGe strain-relaxed buffer layer can be formed by making cuts in, or segmenting, a strained epitaxial film, causing edges of the film segments to experience an elastic strain relaxation. When the segments are small enough, the overall film is relaxed so that the film is substantially without dislocation defects. Once the substantially defect-free strain-relaxed buffer layer is formed, strained channel layers can be grown epitaxially from the relaxed SRB layer. The strained channel layers are then patterned to create fins for a FinFET device. In one embodiment, dual strained channel layers are formed—a tensilely strained layer for NFET devices, and a compressively strained layer for PFET devices.

Abstract: The present invention relates generally to semiconductor devices and more particularly, to a structure and method of forming a fin using double trench epitaxy. The fin may be composed of a III-V semiconductor material and may be grown on a silicon, silicon germanium, or germanium substrate. A double trench aspect ratio trapping (ART) epitaxy method may trap crystalline defects within a first trench (i.e. a defective region) and may permit formation of a fin free of patterning defects in an upper trench (i.e. a fin mold). Crystalline defects within the defective region may be trapped via conventional aspect ratio trapping or three-sided aspect ratio trapping. Fin patterning defects may be avoided by utilizing a fin mold to grow an epitaxial fin and selectively removing dielectric material adjacent to a fin region.

Abstract: Methods for forming semiconductor devices having non-merged fin extensions. Methods for forming semiconductor devices include forming trenches in an insulator layer of a substrate. Fins are formed in the trenches and a dummy gate is formed over the fins, leaving a source and drain region exposed. The fins are etched below a surface level of a surrounding insulator layer. Fin extensions are epitaxially grown from the etched fins.

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: A method of forming multiple vertical transport fin field effect transistors (VT FinFETs) having different channel lengths, including, forming a vertical fin on a first region of a substrate and a vertical fin on a second region of the substrate, forming a cover block on the vertical fin on the second region of the substrate, forming a first bottom source/drain on the first region of the substrate, wherein the first bottom source/drain covers a lower portion of the vertical fin on the first region, removing the cover block, and forming a second bottom source/drain in the second region of the substrate, wherein the second bottom source/drain is below the surface of the substrate, wherein the second bottom source/drain does not cover a lower portion of the vertical fin on the second region.

Abstract: Fabrication method for a semiconductor device and structure are provided, which includes: providing an isolation layer at least partially disposed adjacent to at least one sidewall of a fin structure extended above a substrate structure, the fin structure including a channel region; recessing an exposed portion of the fin structure to define a residual stress to be induced into the channel region of the fin structure, wherein upper surfaces of a recessed fin portion and the isolation layer are coplanar with each other; and epitaxially growing a semiconductor material from the recessed exposed portion of the fin structure to form at least one of a source region and a drain region of the semiconductor device.

Abstract: Voidless contact metal structures are provided. In one embodiment, a voidless contact metal structure is provided by first providing a first contact metal that contains a void within a contact opening. The void is then opened to provide a divot in the first contact metal. After forming a dielectric spacer atop a portion of first contact metal, a second contact metal is then formed that lacks any void. The second contact metal fills the entirety of the divot within the first contact metal. In another embodiment, two diffusion barrier structures are provided within a contact opening, followed by the formation of a contact metal structure that lacks any void.