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: A method is presented for cleaning an ion implanter during operation of the ion implanter. The method includes generating a gallium (III) iodide (GaI3) vapor from a GaI3 source running concurrently with a hydrogen-containing gaseous plasma to cause a reaction with at least iodine (I) residue deposits, selectively filtering ions from the GaI3 vapor and the hydrogen-containing gaseous plasms to create a Ga ion beam, and directing the Ga ion beam onto a semiconductor substrate for Ga implantation. After completion of the Ga implantation, an argon (Ar) based ion beam is run through the ion implanter for post-cleaning of the ion implanter.

Abstract: A method is presented for cleaning an ion implanter during operation of the ion implanter. The method includes generating a gallium (III) iodide (GaI3) vapor from a GaI3 source running concurrently with a hydrogen-containing gaseous plasma to cause a reaction with at least iodine (I) residue deposits, selectively filtering ions from the GaI3 vapor and the hydrogen-containing gaseous plasms to create a Ga ion beam, and directing the Ga ion beam onto a semiconductor substrate for Ga implantation. After completion of the Ga implantation, an argon (Ar) based ion beam is run through the ion implanter for post-cleaning of the ion implanter.

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: 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: Disclosed is an improved semiconductor structure (e.g., a silicon germanium (SiGe) hetero-junction bipolar transistor) having a narrow essentially interstitial-free SIC pedestal with minimal overlap of the extrinsic base. Also, disclosed is a method of forming the transistor which uses laser annealing, as opposed to rapid thermal annealing, of the SIC pedestal to produce both a narrow SIC pedestal and an essentially interstitial-free collector. Thus, the resulting SiGe HBT transistor can be produced with narrower base and collector space-charge regions than can be achieved with conventional technology.

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: 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: A method of forming a semiconductor wafer includes generating a stress topography model of a semiconductor wafer with a plurality of desired structures in a desired layout. The method also includes determining a topography and calculating a compensation pattern based upon the topography, wherein the compensation pattern balances wafer topography. The method also includes patterning a semiconductor front side with the plurality of desired microstructures in the desired layout. The method also includes patterning the semiconductor back side with a compensation block mask corresponding to the compensation pattern.

Abstract: Semiconductor structures and methods of fabricating the same using interrupted deposition processes and multiple laser anneals are provided. The structure includes a high-k gate stack with a high-k bilayer or nanolaminate where a bottom portion of the bilayer is crystallized while a top portion of the bilayer is amorphous.

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.

Abstract: Semiconductor structures and methods of fabricating the same using interrupted deposition processes and multiple laser anneals are provided. The structure includes a high-k gate stack with a high-k bilayer or nanolaminate where a bottom portion of the bilayer is crystallized while a top portion of the bilayer is amorphous.

Abstract: A method of forming a semiconductor device that includes providing a plurality of fin structures, wherein a surface of the fin structures has a first orientation for a diamond shaped epitaxial growth deposition surface. A first epitaxial semiconductor material having a diamond geometry is grown on the diamond shaped epitaxial growth surface. A blocking material is formed protecting a lower portion of the first epitaxial semiconductor material. An upper portion of the first epitaxial semiconductor material is removed to expose a second orientation surface of the first epitaxial semiconductor material for merged epitaxial semiconductor growth. A second epitaxial semiconductor material is epitaxially formed on the first epitaxial semiconductor material. The second epitaxial semiconductor material has a substantially planar upper surface and extends into direct contact with at least two adjacent fin structures.

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 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: 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: A bilayer of silicon dioxide and silicon nitride is formed on exposed surfaces of at least one semiconductor fin having a bottom source/drain region located at the footprint, and on each side, of the at least one semiconductor fin. An upper surface of each horizontal portion of the silicon nitride layer is then carbonized, and thereafter non-carbonized vertical portions of the silicon nitride layer are removed. Next, the carbonized portions of the silicon nitride layer are removed, and thereafter the vertical portions of the silicon dioxide layer are removed from sidewalls of the at least one semiconductor fin utilizing each remaining portion of the silicon nitride layer as an etch mask A bottom spacer structure is provided on each bottom source/drain region in which each bottom spacer structure includes a remaining portion of the silicon dioxide layer and the remaining portion of the silicon nitride 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: A method for fabricating a semiconductor device includes forming a gate stack on a semiconductor substrate, forming a source/drain region on an exposed portion of the substrate, and forming a semiconductor material layer on the source/drain region. A first liner layer is deposited on the semiconductor material layer, and a second liner layer is deposited on the first liner layer. A conductive contact material is deposited on the second liner layer.

Abstract: A bilayer of silicon dioxide and silicon nitride is formed on exposed surfaces of at least one semiconductor fin having a bottom source/drain region located at the footprint, and on each side, of the at least one semiconductor fin. An upper surface of each horizontal portion of the silicon nitride layer is then carbonized, and thereafter non-carbonized vertical portions of the silicon nitride layer are removed. Next, the carbonized portions of the silicon nitride layer are removed, and thereafter the vertical portions of the silicon dioxide layer are removed from sidewalls of the at least one semiconductor fin utilizing each remaining portion of the silicon nitride layer as an etch mask A bottom spacer structure is provided on each bottom source/drain region in which each bottom spacer structure includes a remaining portion of the silicon dioxide layer and the remaining portion of the silicon nitride layer.