Abstract: An FET device characterized as being an asymmetrical tunnel FET (TFET) is disclosed. The TFET includes a gate-stack, a channel region underneath the gate-stack, a first and a second junction adjoining the gate-stack and being capable for electrical continuity with the channel. The first junction and the second junction are of different conductivity types. The TFET also includes spacer formations in a manner that the spacer formation on one side of the gate-stack is thinner than on the other side.

Abstract: A method of forming a lateral bipolar transistor includes forming a silicon on insulator (SOI) substrate having a bottom substrate layer, a buried oxide layer (BOX) on top of the substrate layer, and a silicon on insulator (SOI) layer on top of the BOX layer, forming a dummy gate and spacer on top of the silicon on insulator layer, doping the SOI layer with positive or negative ions, depositing an inter layer dielectric (ILD), using chemical mechanical planarization (CMP) to planarize the ILD, removing the dummy gate creating a gate trench which reveals the base of the dummy gate, doping the dummy gate base, depositing a layer of polysilicon on top of the SOI layer and into the gate trench, etching the layer of polysilicon so that it only covers the dummy gate base, and applying a self-aligned silicide process.

Abstract: A method for fabricating a transistor having self-aligned borderless electrical contacts is disclosed. A gate stack is formed on a silicon region. An off-set spacer is formed surrounding the gate stack. A sacrificial layer that includes a carbon-based film is deposited overlying the silicon region, the gate stack, and the off-set spacer. A pattern is defined in the sacrificial layer to define a contact area for the electrical contact. The pattern exposes at least a portion of the gate stack and source/drain. A dielectric layer is deposited overlying the sacrificial layer that has been patterned and the portion of the gate stack that has been exposed. The sacrificial layer that has been patterned is selectively removed to define the contact area at the height that has been defined. The contact area for the height that has been defined is metalized to form the electrical contact.

Abstract: A semiconductor device (e.g., field effect transistor (FET)) having an asymmetric feature, includes a first gate formed on a substrate, first and second diffusion regions formed in the substrate on a side of the first gate, and first and second contacts which contact the first and second diffusion regions, respectively, the first contact being asymmetric with respect to the second contact.

Abstract: A nanowire tunnel field effect transistor (FET) device includes a channel region including a silicon portion having a first distal end and a second distal end, the silicon portion is surrounded by a gate structure disposed circumferentially around the silicon portion, a drain region including an doped silicon portion extending from the first distal end, a portion of the doped silicon portion arranged in the channel region, a cavity defined by the second distal end of the silicon portion and an inner diameter of the gate structure, and a source region including a doped epi-silicon portion epitaxially extending from the second distal end of the silicon portion in the cavity, a first pad region, and a portion of a silicon substrate.

Abstract: A method for fabricating an upside-down p-FET includes: fully etching source and drain regions in a donor substrate by etching a silicon-on-insulator layer through buried oxide and partially etching the silicon substrate; refilling a bottom and sidewall surfaces of the etched source and drain regions with epitaxial silicide/germanide to form e-SiGe source and drain regions; capping the source and drain regions with self-aligning silicide/germanide; providing a silicide layer formed over the gate conductor line; providing a first stress liner over the gate and the e-SiGe source and drain regions; depositing a planarized dielectric over the self-aligning silicide/germanide; inverting the donor substrate; bonding the donor substrate to a host wafer; and selectively exposing the buried oxide and the e-SiGe source and drain regions by removing the donor wafer.

Abstract: A method for fabricating recessed source and recessed drain regions of aggressively scaled CMOS devices. In this method a processing sequence of plasma etch, deposition, followed by plasma etch is used to controllably form recessed regions of the source and the drain in the channel of a thin body, much less than 40 nm, device to enable subsequent epitaxial growth of SiGe, SiC, or other materials, and a consequent increase in the device and ring oscillator performance. A Field Effect Transistor device is also provided, which includes: a buried oxide layer; a silicon layer above the buried oxide layer; an isotropically recessed source region; an isotropically recessed drain region; and a gate stack which includes a gate dielectric, a conductive material, and a spacer.

Abstract: Non-planar semiconductor devices are provided that include at least one semiconductor nanowire suspended above a semiconductor oxide layer that is present on a first portion of a bulk semiconductor substrate. An end segment of the at least one semiconductor nanowire is attached to a first semiconductor pad region and another end segment of the at least one semiconductor nanowire is attached to a second semiconductor pad region. The first and second pad regions are located above and are in direct contact with a second portion of the bulk semiconductor substrate which is vertically offsets from the first portion. The structure further includes a gate surrounding a central portion of the at least one semiconductor nanowire, a source region located on a first side of the gate, and a drain region located on a second side of the gate which is opposite the first side of the gate.

Abstract: A CMOS chip comprising a high performance device region and a high density device region includes a plurality of high performance devices comprising n-type field effect transistors (NFETs) and p-type field effect transistors (PFETs) in the high performance device region, wherein the high performance devices have a high performance pitch; and a plurality of high density devices comprising NFETs and PFETs in the high density device region, wherein the high density devices have a high density pitch, and wherein the high performance pitch is about 2 to 3 times the high density pitch; wherein the high performance device region comprises doped source and drain regions, NFET gate regions having an elevated stress induced using stress memorization technique (SMT), gate silicide and source/drain silicide regions, and a dual stressed liner, and wherein the high density device region comprises doped source and drain regions, gate silicide regions, and a neutral stressed liner.

Abstract: Techniques for gate workfunction engineering using a workfunction setting material to reduce short channel effects in planar CMOS devices are provided. In one aspect, a method of fabricating a CMOS device includes the following steps. A SOI wafer is provided having a SOI layer over a BOX. A patterned dielectric is formed on the wafer having trenches therein present over active areas in which a gate stack will be formed. Into each of the trenches depositing: (i) a conformal gate dielectric (ii) a conformal gate metal layer and (iii) a conformal workfunction setting metal layer. A volume of the conformal gate metal layer and/or a volume of the conformal workfunction setting metal layer deposited into a given one of the trenches are/is proportional to a length of the gate stack being formed in the given trench. A CMOS device is also provided.

Abstract: A method for forming a nanowire field effect transistor (FET) device, the method includes forming a suspended nanowire over a semiconductor substrate, forming a gate structure around a portion of the nanowire, forming a protective spacer adjacent to sidewalls of the gate and around portions of nanowire extending from the gate, removing exposed portions of the nanowire left unprotected by the spacer structure, and epitaxially growing a doped semiconductor material on exposed cross sections of the nanowire to form a source region and a drain region.

Abstract: A method of forming a lateral bipolar transistor. The method includes forming a silicon on insulator (SOI) substrate having a bottom substrate layer, a buried oxide layer (BOX) on top of the substrate layer, and a silicon on insulator (SOI) layer on top of the BOX layer, forming a dummy gate and spacer on top of the silicon on insulator layer, doping the SOI layer with positive or negative ions, depositing an inter layer dielectric (ILD), using chemical mechanical planarization (CMP) to planarize the ILD, removing the dummy gate creating a gate trench which reveals the base of the dummy gate, doping the dummy gate base, depositing a layer of polysilicon on top of the SOI layer and into the gate trench, etching the layer of polysilicon so that it only covers the dummy gate base, and applying a self-aligned silicide process.

Abstract: Techniques are provided for gate work function engineering in FIN FET devices using a work function setting material an amount of which is provided proportional to fin pitch. In one aspect, a method of fabricating a FIN FET device includes the following steps. A SOI wafer having a SOI layer over a BOX is provided. An oxide layer is formed over the SOI layer. A plurality of fins is patterned in the SOI layer and the oxide layer. An interfacial oxide is formed on the fins. A conformal gate dielectric layer, a conformal gate metal layer and a conformal work function setting material layer are deposited on the fins. A volume of the conformal gate metal layer and a volume of the conformal work function setting material layer deposited over the fins is proportional to a pitch of the fins. A FIN FET device is also provided.

Abstract: Techniques are provided for gate work function engineering in FIN FET devices using a work function setting material an amount of which is provided proportional to fin pitch. In one aspect, a FIN FET device is provided. The FIN FET device includes a SOI wafer having an oxide layer and a SOI layer over a BOX, and a plurality of fins patterned in the oxide layer and the SOI layer; an interfacial oxide on the fins; and at least one gate stack on the interfacial oxide, the gate stack having (i) a conformal gate dielectric layer present, (ii) a conformal gate metal layer, and (iii) a conformal work function setting material layer. A volume of the conformal gate metal layer and a volume of the conformal work function setting material layer present in the gate stack is proportional to a pitch of the fins.

Abstract: Techniques are provided for gate work function engineering in FIN FET devices using a work function setting material an amount of which is provided proportional to fin pitch. In one aspect, a FIN FET device is provided. The FIN FET device includes a SOI wafer having an oxide layer and a SOI layer over a BOX, and a plurality of fins patterned in the oxide layer and the SOI layer; an interfacial oxide on the fins; and at least one gate stack on the interfacial oxide, the gate stack having (i) a conformal gate dielectric layer present, (ii) a conformal gate metal layer, and (iii) a conformal work function setting material layer. A volume of the conformal gate metal layer and a volume of the conformal work function setting material layer present in the gate stack is proportional to a pitch of the fins.

Abstract: Techniques are provided for gate work function engineering in FIN FET devices using a work function setting material an amount of which is provided proportional to fin pitch. In one aspect, a method of fabricating a FIN FET device includes the following steps. A SOI wafer having a SOI layer over a BOX is provided. An oxide layer is formed over the SOI layer. A plurality of fins is patterned in the SOI layer and the oxide layer. An interfacial oxide is formed on the fins. A conformal gate dielectric layer, a conformal gate metal layer and a conformal work function setting material layer are deposited on the fins. A volume of the conformal gate metal layer and a volume of the conformal work function setting material layer deposited over the fins is proportional to a pitch of the fins. A FIN FET device is also provided.

Abstract: In one aspect, a CMOS device is provided. The CMOS device includes a SOI wafer having a SOI layer over a BOX; one or more active areas formed in the SOI layer in which one or more FET devices are formed, each of the FET devices having an interfacial oxide on the SOI layer and a gate stack on the interfacial oxide layer, the gate stack having (i) a conformal gate dielectric layer present on a top and sides of the gate stack, (ii) a conformal gate metal layer lining the gate dielectric layer, and (iii) a conformal workfunction setting metal layer lining the conformal gate metal layer. A volume of the conformal gate metal layer and/or a volume of the conformal workfunction setting metal layer present in the gate stack are/is proportional to a length of the gate stack.

Abstract: A nanowire FET device includes a SOI wafer having a SOI layer over a BOX, and a plurality of nanowires and pads patterned in the SOI layer, wherein the nanowires are suspended over the BOX; an interfacial oxide surrounding each of the nanowires; and at least one gate stack surrounding each of the nanowires, the gate stack having (i) a conformal gate dielectric present on the interfacial oxide (ii) a conformal first gate material on the conformal gate dielectric (iii) a work function setting material on the conformal first gate material, and (iv) a second gate material on the work function setting material. A volume of the conformal first gate material and/or a volume of the work function setting material in the gate stack are/is proportional to a pitch of the nanowires.

Abstract: A method of fabricating a nanowire FET device includes the following steps. A SOI wafer is provided having a SOI layer over a BOX. Nanowires and pads are etched in the SOI layer. The nanowires are suspended over the BOX. An interfacial oxide is formed surrounding each of the nanowires. A conformal gate dielectric is deposited on the interfacial oxide. A conformal first gate material is deposited on the conformal gate dielectric. A work function setting material is deposited on the conformal first gate material. A second gate material is deposited on the work function setting material to form at least one gate stack over the nanowires. A volume of the conformal first gate material and/or a volume of the work function setting material in the gate stack are/is proportional to a pitch of the nanowires.

Abstract: A method of fabricating a nanowire FET device includes the following steps. A SOI wafer is provided having a SOI layer over a BOX. Nanowires and pads are etched in the SOI layer. The nanowires are suspended over the BOX. An interfacial oxide is formed surrounding each of the nanowires. A conformal gate dielectric is deposited on the interfacial oxide. A conformal first gate material is deposited on the conformal gate dielectric. A work function setting material is deposited on the conformal first gate material. A second gate material is deposited on the work function setting material to form at least one gate stack over the nanowires. A volume of the conformal first gate material and/or a volume of the work function setting material in the gate stack are/is proportional to a pitch of the nanowires.