Abstract: A field effect transistor (FET) structure includes: a gate; a first spacer having a first dielectric constant at a first region adjacent to the gate; and a second spacer having a second dielectric constant that is greater than the first dielectric constant at a second region adjacent to the gate.

Abstract: A vertical field effect device includes a substrate and a vertical channel including InxGa1-xAs on the substrate. The vertical channel includes a pillar that extends from the substrate and includes opposing vertical surfaces. The device further includes a stressor layer on the opposing vertical surfaces of the vertical channel. The stressor layer includes a layer of epitaxial crystalline material that is epitaxially formed on the vertical channel and that has lattice constant in a vertical plane corresponding to one of the opposing vertical surfaces of the vertical channel that is greater than a corresponding lattice constant of the vertical channel.

Abstract: A semiconductor device includes: a substrate; a power rail on the substrate; an active layer on the substrate and at same layer as the power rail; and a contact electrically connecting the power rail to the active layer. The active layer includes source/drain terminals.

Abstract: Methods of forming nanosheets for a semiconductor device are provided including providing a silicon on insulator (SOI) handle wafer, the SOT handle wafer including a silicon layer and a dielectric layer on the silicon layer; providing a first donor wafer; bonding the SOI handle wafer and the first donor wafer together to provide a bonded structure; debonding the bonded structure to provide an intermediate wafer including a plurality of silicon or non-silicon nano sheets and a plurality of dielectric layers alternately stacked; and bonding the intermediate wafer to a second donor wafer to provide a final wafer including a plurality of silicon or non-silicon layers and a plurality of dielectric layers alternately stacked, wherein the final wafer includes at least one more pair of silicon or non-silicon and dielectric layers than the intermediate wafer.

Abstract: A diffusion barrier and a method to form the diffusion bather are disclosed. A trench structure is formed in an Inter Layer Dielectric (ILD). The ILD comprises a dielectric matrix having a first density. A dopant material layer is formed on the trench structure in which the dopant material layer comprises atoms of at least one of a rare-earth element. The ILD and the trench structure are annealed to form a dielectric matrix comprising a second density in one or more regions of the ILD on which the dopant material layer was formed that is greater than the first density. After annealing, the dielectric matrix comprising the second density includes increased bond lengths of oxygen-silicon bonds and/or oxygen-semiconductor bonds, increased bond angles of oxygen-silicon bonds and/or oxygen-semiconductor material bonds, and pores in the dielectric matrix are sealed compared to the dielectric matrix comprising the first density.

Abstract: A method is disclosed to form a metal-oxysilicate diffusion barrier for a damascene metallization. A trench is formed in an Inter Layer Dielectric (ILD) material. An oxysilicate formation-enhancement layer comprising silicon, carbon, oxygen, a constituent component of the ILD, or a combination thereof, is formed in the trench. A barrier seed layer is formed on the oxysilicate formation-enhancement layer comprising an elemental metal selected from a first group of elemental metals in combination with an elemental metal selected from a second group of elemental metals. An elemental metal in the second group is immiscible in copper or an alloy thereof, has a diffusion constant greater than a self-diffusion of copper or an alloy thereof; does not reducing silicon-oxygen bonds during oxysilicate formation; and promotes adhesion of copper or an alloy of copper to the metal-oxysilicate barrier diffusion layer. The structure is then annealed to form a metal-oxysilicate diffusion barrier.

Abstract: A field effect transistor (FET) and a method to form the FET are disclosed. The FET comprises a channel region comprising a nanosheet layer/sacrificial layer stack. The stack comprises at least one nanosheet layer/sacrificial layer pair. Each nanosheet layer/sacrificial layer pair comprises an end surface. A conductive material layer is formed on the end surface of the pairs, and a source/drain contact is formed on the conductive material layer. In one embodiment, the sacrificial layer of at least one pair further may comprise a low-k dielectric material proximate to the end surface of the pair. A surface of the low-k dielectric material proximate to the end surface of the pair is in substantial alignment with the end surface of the nanosheet layer. Alternatively, the surface of the low-k dielectric material proximate to the end surface of the pair is recessed with respect to the end surface of the nanosheet layer.

Abstract: The present invention provides a trench isolation structure, a method of manufacture therefor and a method for manufacturing an integrated circuit including the same. The trench isolation structure (130), in one embodiment, includes a trench located within a substrate (110), the trench having an implanted buffer layer (133) located in the sidewalls thereof. The trench isolation structure (130) further includes a barrier layer (135) located over the implanted buffer layer (133), and fill material (138) located over the barrier layer (135) and substantially filling the trench.

Abstract: In one aspect, the present invention provides a method of forming junctions in a silicon-germanium layer (20). In this particular embodiment, the method comprises implanting a dopant (80) into the silicon-germanium layer (20) and implanting fluorine (70) into the silicon-germanium layer (20).

Abstract: A new MOS transistor is described. The transistor has a source/drain region that comprises 3 portions. Each portion is the result of a separate ion implant step. The combination of the three portions of the source/drain region yields a transistor of superior performance with high drive current, low sub-threshold current and gate-edge leakage.

Abstract: In one aspect, the present invention provides a method of forming junctions in a silicon-germanium layer (20). In this particular embodiment, the method comprises implanting a dopant (80) into the silicon-germanium layer (20) and implanting fluorine (70) into the silicon-germanium layer (20).

Abstract: The present invention provides a trench isolation structure, a method of manufacture therefor and a method for manufacturing an integrated circuit including the same. The trench isolation structure (130), in one embodiment, includes a trench located within a substrate (110), the trench having a buffer layer (133) located on sidewalls thereof. The trench isolation structure (130) further includes a barrier layer (135) located over the buffer layer (133), and fill material (138) located over the barrier layer (135) and substantially filling the trench.

Abstract: The present invention provides a trench isolation structure, a method of manufacture therefor and a method for manufacturing an integrated circuit including the same. The trench isolation structure (130), in one embodiment, includes a trench located within a substrate (110), the trench having an implanted buffer layer (133) located in the sidewalls thereof. The trench isolation structure (130) further includes a barrier layer (135) located over the implanted buffer layer (133), and fill material (138) located over the barrier layer (135) and substantially filling the trench.

Abstract: A new MOS transistor is described. The transistor has a source/drain region that comprises 3 portions. Each portion is the result of an separate ion implant step. The combination of the three portions of the source/drain region yields a transistor of superior performance with high drive current, low sub-threshold current and gate-edge leakage.

Abstract: A process (10) for the production of a transistor device with reduced gate depletion is disclosed. The system includes providing a semiconductor substrate, forming a gate dielectric on an active area on the upper surface portion of the substrate and depositing a gate layer on top of the gate oxide. Next, the gate is implanted (12) with Boron and the N-doped regions of gate are patterned (14) and implanted (16).