Abstract: A method for forming an electrical device that includes forming a high-k gate dielectric layer over a semiconductor substrate that is patterned to separate a first portion of the high-k gate dielectric layer that is present on a first conductivity device region from a second portion of the high-k gate dielectric layer that is present on a second conductivity device region. A connecting gate conductor is formed on the first portion and the second portion of the high-k gate dielectric layer. The connecting gate conductor extends from the first conductivity device region over the isolation region to the second conductivity device region. One of the first conductivity device region and the second conductivity device region may then be exposed to an oxygen containing atmosphere. Exposure with the oxygen containing atmosphere modifies a threshold voltage of the semiconductor device that is exposed.

Abstract: A structure includes a silicon substrate; at least two wells in the silicon substrate; and a deep trench isolation (DTI) separating the two wells. The DTI has a top portion and a bottom portion having a width that is larger than a width of the top portion. The structure further includes at least two semiconductor devices disposed over one of the wells, where the at least two semiconductor devices are separated by a shallow trench isolation (STI). In the structure sidewalls of the top portion of the DTI and sidewalls of the STI are comprised of doped, re-crystallized silicon. The doped, re-crystallized silicon can be formed by an angled ion implant that uses, for example, one of Xe, In, BF2, B18H22, C16H10, Si, Ge or As as an implant species to amorphize the silicon, and by annealing the amorphized silicon to re-crystallize the amorphized silicon.

Abstract: Shallow trench isolation structures are provided for use with UTBB (ultra-thin body and buried oxide) semiconductor substrates, which prevent defect mechanisms from occurring, such as the formation of electrical shorts between exposed portions of silicon layers on the sidewalls of shallow trench of a UTBB substrate, in instances when trench fill material of the shallow trench is subsequently etched away and recessed below an upper surface of the UTBB substrate.

Abstract: A semiconductor device includes at least one first semiconductor fin formed on an nFET region of a semiconductor device and at least one second semiconductor fin formed on a pFET region. The at least one first semiconductor fin has an nFET channel region interposed between a pair of nFET source/drain regions. The at least one second semiconductor fin has a pFET channel region interposed between a pair of pFET source/drain regions. The an epitaxial liner is formed on only the pFET channel region of the at least one second semiconductor fin such that a first threshold voltage of the nFET channel region is different than a second threshold voltage of the pFET channel.

Abstract: A semiconductor device includes at least one first semiconductor fin formed on an nFET region of a semiconductor device and at least one second semiconductor fin formed on a pFET region. The at least one first semiconductor fin has an nFET channel region interposed between a pair of nFET source/drain regions. The at least one second semiconductor fin has a pFET channel region interposed between a pair of pFET source/drain regions. The an epitaxial liner is formed on only the pFET channel region of the at least one second semiconductor fin such that a first threshold voltage of the nFET channel region is different than a second threshold voltage of the pFET channel.

Abstract: A method of forming a semiconductor device that includes forming a fin structure from a semiconductor substrate, and forming a gate structure on a channel region portion of the fin structure. A source region and a drain region are formed on a source region portion and a drain region portion of the fin structure on opposing sides of the channel portion of the fin structure. At least one sidewall of the source region portion and the drain region portion of the fin structure is exposed. A metal semiconductor alloy is formed on the at least one sidewall of the source region portion and the drain region portion of the fin structure that is exposed.

Abstract: A semiconductor device and a method for fabricating the device. The method includes: providing a FinFET having a source/drain region, at least one SiGe fin, a silicon substrate, a local oxide layer is formed on the silicon substrate, a gate structure is formed on the at least one SiGe fin and the local oxide layer, the gate structure is encapsulated by a gate hard mask and sidewall spacer layers; recessing the at least one SiGe fin in the source/drain region to the sidewall spacer layers and the silicon substrate layer; recessing the local oxide layer in the source/drain region to the sidewall spacer layer and the silicon substrate; growing a n-doped silicon layer on the silicon substrate; growing a p-doped silicon layer or p-doped SiGe layer on the n-doped silicon layer; and forming a silicide layer on the p-doped silicon layer or p-doped SiGe layer.

Abstract: Semiconductor fins are formed on a top surface of a substrate. A dielectric material is deposited on the top surfaces of the semiconductor fins and the substrate by an anisotropic deposition. A dielectric material layer on the top surface of the substrate is patterned so that the remaining portion of the dielectric material layer laterally surrounds each bottom portion of at least one semiconductor fin, while not contacting at least one second semiconductor fin. Dielectric material portions on the top surfaces of the semiconductor fins may be optionally removed. Each first semiconductor fin has a lesser channel height than the at least one second semiconductor fin. The first and second semiconductor fins can be employed to provide fin field effect transistors having different channel heights.

Abstract: Semiconductor fins are formed on a top surface of a substrate. A dielectric material is deposited on the top surfaces of the semiconductor fins and the substrate by an anisotropic deposition. A dielectric material layer on the top surface of the substrate is patterned so that the remaining portion of the dielectric material layer laterally surrounds each bottom portion of at least one semiconductor fin, while not contacting at least one second semiconductor fin. Dielectric material portions on the top surfaces of the semiconductor fins may be optionally removed. Each first semiconductor fin has a lesser channel height than the at least one second semiconductor fin. The first and second semiconductor fins can be employed to provide fin field effect transistors having different channel heights.

Abstract: An electrical circuit, planar diode, and method of forming a diode and one or more CMOS devices on the same chip. The method includes electrically isolating a portion of a substrate in a diode region from other substrate regions. The method also includes recessing the substrate in the diode region. The method further includes epitaxially forming in the diode region a first doped layer above the substrate and epitaxially forming in the diode region a second doped layer above the first doped layer.

Abstract: An SOI substrate, a semiconductor device, and a method of backgate work function tuning. The substrate and the device have a plurality of metal backgate regions wherein at least two regions have different work functions. The method includes forming a mask on a substrate and implanting a metal backgate interposed between a buried oxide and bulk regions of the substrate thereby producing at least two metal backgate regions having different doses of impurity and different work functions. The work function regions can be aligned such that each transistor has different threshold voltage. When a top gate electrode serves as the mask, a metal backgate with a first work function under the channel region and a second work function under the source/drain regions is formed. The implant can be tilted to shift the work function regions relative to the mask.

Abstract: Shallow trench isolation structures are provided for use with UTBB (ultra-thin body and buried oxide) semiconductor substrates, which prevent defect mechanisms from occurring, such as the formation of electrical shorts between exposed portions of silicon layers on the sidewalls of shallow trench of a UTBB substrate, in instances when trench fill material of the shallow trench is subsequently etched away and recessed below an upper surface of the UTBB substrate.

Abstract: Methods for forming a buried-channel field-effect transistor include doping source and drain regions on a substrate with a dopant having a first type; forming a doped shielding layer on the substrate in a channel region having a second doping type opposite the first type to displace a conducting channel away from a gate-interface region; forming a gate dielectric over the doped shielding layer; and forming a gate on the gate dielectric.

Abstract: A FinFet device structure provided with a thin layer of polycrystalline silicon having stress containing material, including a high Ge percentage silicon germanium film and/or a high stress W film on top of a polycrystalline silicon film. Space between the fins enables the stressor films to be positioned closer to the transistor channel. The improved proximity of the stress containing material to the transistor channel and the enhanced stress couple the efficiency defines a ratio between the stress level in the stressor film and stress transfer to the channel for mobility enhancement. The stress level is further enhanced by patterning by removal of the n-type workfunction metal from the p-FinFET. Following the stripping off the soft or hard mask, the p-type workfunction metal ends positioned in the n- and p-FinFET regions. The freed space specifically for p-FinFet between the fins achieves an even higher stressor coupling to further boost the carrier mobility.

Abstract: An SOI substrate, a semiconductor device, and a method of backgate work function tuning. The substrate and the device have a plurality of metal backgate regions wherein at least two regions have different work functions. The method includes forming a mask on a substrate and implanting a metal backgate interposed between a buried oxide and bulk regions of the substrate thereby producing at least two metal backgate regions having different doses of impurity and different work functions. The work function regions can be aligned such that each transistor has different threshold voltage. When a top gate electrode serves as the mask, a metal backgate with a first work function under the channel region and a second work function under the source/drain regions is formed. The implant can be tilted to shift the work function regions relative to the mask.

Abstract: A FinFet formed by depositing a thin layer of polycrystalline silicon followed by depositing a stress containing material, including a high Ge percentage silicon germanium film and/or a high stress W film on top of a polycrystalline silicon film. Freeing space between fins allows stressor films to be deposited closer to the transistor channel, improving the proximity of the stress containing material to the transistor channel and enhancing the stress coupling efficiency by defining a ratio between stress level in the stressor film and stress transferred to the channel for a mobility enhancement. The stress level is enhanced by patterning by removing the n-type workfunction metal from the p-FinFET. After stripping off the soft or hard mask, the p-type workfunction metal is deposited in the n- and p-FinFET regions. The freed space specifically for p-FinFet between the fins achieves an even higher stressor coupling to further boost the carrier mobility.

Abstract: Carbon-doped semiconductor material portions are formed on a subset of surfaces of underlying semiconductor surfaces contiguously connected to a channel of a field effect transistor. Carbon-doped semiconductor material portions can be formed by selective epitaxy of a carbon-containing semiconductor material layer or by shallow implantation of carbon atoms into surface portions of the underlying semiconductor surfaces. The carbon-doped semiconductor material portions can be deposited as layers and subsequently patterned by etching, or can be formed after formation of disposable masking spacers. Raised source and drain regions are formed on the carbon-doped semiconductor material portions and on physically exposed surfaces of the underlying semiconductor surfaces.

Abstract: A FinFet formed by depositing a thin layer of polycrystalline silicon followed by depositing a stress containing material, including a high Ge percentage silicon germanium film and/or a high stress W film on top of a polycrystalline silicon film. Freeing space between fins allows stressor films to be deposited closer to the transistor channel, improving the proximity of the stress containing material to the transistor channel and enhancing the stress coupling efficiency by defining a ratio between stress level in the stressor film and stress transferred to the channel for a mobility enhancement. The stress level is enhanced by patterning by removing the n-type workfunction metal from the p-FinFET. After stripping off the soft or hard mask, the p-type workfunction metal is deposited in the n- and p-FinFET regions. The freed space specifically for p-FinFet between the fins achieves an even higher stressor coupling to further boost the carrier mobility.

Abstract: A method for manufacturing a fin field-effect transistor (FinFET) device, comprises forming a plurality of fins on a substrate, forming a plurality of gate regions on portions of the fins, wherein the gate regions are spaced apart from each other, forming spacers on each respective gate region, epitaxially growing a first epitaxy region on each of the fins, stopping growth of the first epitaxy regions prior to merging of the first epitaxy regions between adjacent fins, forming a dielectric layer on the substrate including the fins and first epitaxy regions, removing the dielectric layer and first epitaxy regions from the fins at one or more portions between adjacent gate regions to form one or more contact area trenches, and epitaxially growing a second epitaxy region on each of the fins in the one or more contact area trenches, wherein the second epitaxy regions on adjacent fins merge with each other.

Abstract: A semiconductor device includes an epitaxy layer formed on semiconductor substrate, a device layer formed on the epitaxy layer, a trench formed within the semiconductor substrate and including a dielectric layer forming a liner within the trench and a conductive core forming a through-silicon via conductor, and a deep trench isolation structure formed within the substrate and surrounding the through-silicon via conductor. A region of the epitaxy layer formed between the through-silicon via conductor and the deep trench isolation structure is electrically isolated from any signals applied to the semiconductor device, thereby decreasing parasitic capacitance.