Abstract: Two trenches having different widths are formed in a semiconductor-on-insulator (SOI) substrate. An oxygen-impermeable layer and a fill material layer are formed in the trenches. The fill material layer and the oxygen-impermeable layer are removed from within a first trench. A thermal oxidation is performed to convert semiconductor materials underneath sidewalls of the first trench into an upper thermal oxide portion and a lower thermal oxide portion, while the remaining oxygen-impermeable layer on sidewalls of a second trench prevents oxidation of the semiconductor materials. After formation of a node dielectric on sidewalls of the second trench, a conductive material is deposited to fill the trenches, thereby forming a conductive trench fill portion and an inner electrode, respectively. The upper and lower thermal oxide portions function as components of dielectric material portions that electrically isolate two device regions.

Abstract: An enhanced negative resistance voltage controlled oscillator (VCO) is provided, in which the body of each transistor within a pair of cross-coupled transistors is coupled to the gate of the same transistor through a resistor. The body transconductance is employed to enhance the negative resistance of the cross-coupled pair of transistors. At the same time, a forward body bias voltage reduces the threshold voltage of the cross-coupled pair to allow the VCO to operate at a low power supply voltage. Further, the resistor connected between the body and the drain of each transistor voids the leakage in the substrate, and thus, reduces power consumption of the VCO further. This VCO provides low power operation with enhanced figure of merit without employing any extra inductors besides the inductors that are part of the LC tank.

Abstract: A method includes forming patterned lines on a substrate having a predetermined pitch. The method further includes forming spacer sidewalls on sidewalls of the patterned lines. The method further includes forming material in a space between the spacer sidewalls of adjacent patterned lines. The method further includes forming another patterned line from the material by protecting the material in the space between the spacer sidewalls of adjacent patterned lines while removing the spacer sidewalls. The method further includes transferring a pattern of the patterned lines and the patterned line to the substrate.

Abstract: A method of forming improved spacer isolation in deep trench including recessing a node dielectric, a first conductive layer, and a second conductive layer each deposited within a deep trench formed in a silicon-on-insulator (SOI) substrate, to a level below a buried oxide layer of the SOI substrate, and creating an opening having a bottom surface in the deep trench. Further including depositing a spacer along a sidewall of the deep trench and the bottom surface of the opening, and removing the spacer from the bottom surface of the opening. Performing at least one of an ion implantation and an ion bombardment in one direction at an angle into an upper portion of the spacer. Removing the upper portion of the spacer from the sidewall of the deep trench. Depositing a third conductive layer within the opening.

Abstract: A semiconductor structure is provided that includes a material stack including an epitaxially grown semiconductor layer on a base semiconductor layer, a dielectric layer on the epitaxially grown semiconductor layer, and an upper semiconductor layer present on the dielectric layer. A capacitor is present extending from the upper semiconductor layer through the dielectric layer into contact with the epitaxially grown semiconductor layer. The capacitor includes a node dielectric present on the sidewalls of the trench and an upper electrode filling at least a portion of the trench. A substrate contact is present in a contact trench extending from the upper semiconductor layer through the dielectric layer and the epitaxially semiconductor layer to a doped region of the base semiconductor layer. A substrate contact is also provided that contacts the base semiconductor layer through the sidewall of a trench. Methods for forming the above-described structures are also provided.

Abstract: After formation of a gate stack, regions in which a source and a drain are to be formed are recessed through the top semiconductor layer and into an upper portion of a buried single crystalline rare earth oxide layer of a semiconductor-on-insulator (SOI) substrate so that a source trench and drain trench are formed. An embedded single crystalline semiconductor portion epitaxially aligned to the buried single crystalline rare earth oxide layer is formed in each of the source trench and the drain trench to form a recessed source and a recessed drain, respectively. Protrusion of the recessed source and recessed drain above the bottom surface of a gate dielectric can be minimized to reduce parasitic capacitive coupling with a gate electrode, while providing low source resistance and drain resistance through the increased thickness of the recessed source and recessed drain relative to the thickness of the top semiconductor layer.

Abstract: A structural alternative to retro doping to reduce transistor leakage is provided by providing a liner in a trench, undercutting a conduction channel region in an active semiconductor layer, etching a side, corner and/or bottom of the conduction channel where the undercut exposes semiconductor material in the active layer and replacing the removed portion of the conduction channel with insulator. This shaping of the conduction channel increases the distance to adjacent circuit elements which, if charged, could otherwise induce a voltage and cause a change in back-channel threshold in regions of the conduction channel and narrows and reduces cross-sectional area of the channel where the conduction in the channel is not well-controlled; both of which effects significantly reduce leakage of the transistor.

Abstract: An enhanced negative resistance voltage controlled oscillator (VCO) is provided, in which the body of each transistor within a pair of cross-coupled transistors is coupled to the gate of the same transistor through a resistor. The body transconductance is employed to enhance the negative resistance of the cross-coupled pair of transistors. At the same time, a forward body bias voltage reduces the threshold voltage of the cross-coupled pair to allow the VCO to operate at a low power supply voltage. Further, the resistor connected between the body and the drain of each transistor voids the leakage in the substrate, and thus, reduces power consumption of the VCO further. This VCO provides low power operation with enhanced figure of merit without employing any extra inductors besides the inductors that are part of the LC tank.

Abstract: A semiconductor-on-insulator (SOI) substrate comprises a bulk semiconductor substrate, a buried insulator layer formed on the bulk substrate and an active semiconductor layer formed on the buried insulator layer. Impurities are implanted near the interface of the buried insulator layer and the active semiconductor layer. A diffusion barrier layer is formed between the impurities and an upper surface of the active semiconductor layer. The diffusion barrier layer prevents the impurities from diffusing therethrough.

Abstract: A method of forming a trench structure that includes forming a metal containing layer on at least the sidewalls of a trench, and forming an undoped semiconductor fill material within the trench. The undoped semiconductor fill material and the metal containing layer are recessed to a first depth within the trench with a first etch. The undoped semiconductor fill material is then recessed to a second depth within the trench that is greater than a first depth with a second etch. The second etch exposes at least a sidewall portion of the metal containing layer. The trench is filled with a doped semiconductor containing material fill, wherein the doped semiconductor material fill is in direct contact with the at least the sidewall portion of the metal containing layer.

Abstract: Two trenches having different widths are formed in a semiconductor-on-insulator (SOI) substrate. An oxygen-impermeable layer and a fill material layer are formed in the trenches. The fill material layer and the oxygen-impermeable layer are removed from within a first trench. A thermal oxidation is performed to convert semiconductor materials underneath sidewalls of the first trench into an upper thermal oxide portion and a lower thermal oxide portion, while the remaining oxygen-impermeable layer on sidewalls of a second trench prevents oxidation of the semiconductor materials. After formation of a node dielectric on sidewalls of the second trench, a conductive material is deposited to fill the trenches, thereby forming a conductive trench fill portion and an inner electrode, respectively. The upper and lower thermal oxide portions function as components of dielectric material portions that electrically isolate two device regions.

Abstract: A method includes forming patterned lines on a substrate having a predetermined pitch. The method further includes forming spacer sidewalls on sidewalls of the patterned lines. The method further includes forming material in a space between the spacer sidewalls of adjacent patterned lines. The method further includes forming another patterned line from the material by protecting the material in the space between the spacer sidewalls of adjacent patterned lines while removing the spacer sidewalls. The method further includes transferring a pattern of the patterned lines and the another patterned line to the substrate.

Abstract: A method of forming a field effect transistor (FET) device includes forming a gate structure over a substrate, the gate structure including a wide bottom portion and a narrow portion formed on top of the bottom portion; the wide bottom portion comprising a metal material and having a first width that corresponds substantially to a transistor channel length, and the narrow portion also including a metal material having a second width smaller than the first width.

Abstract: A method of forming a deep trench capacitor in a semiconductor-on-insulator substrate is provided. The method may include providing a pad layer positioned above a bulk substrate, etching a deep trench into the pad layer and the bulk substrate extending from a top surface of the pad layer down to a location within the bulk substrate, and doping a portion of the bulk substrate to form a buried plate. The method further including depositing a node dielectric, an inner electrode, and a dielectric cap substantially filling the deep trench, the node dielectric being located between the buried plate and the inner electrode, the dielectric cap being located at a top of the deep trench, removing the pad layer, growing an insulator layer on top of the bulk substrate, and growing a semiconductor-on-insulator layer on top of the insulator layer.

Abstract: After formation of a gate stack, regions in which a source and a drain are to be formed are recessed through the top semiconductor layer and into an upper portion of a buried single crystalline rare earth oxide layer of a semiconductor-on-insulator (SOI) substrate so that a source trench and drain trench are formed. An embedded single crystalline semiconductor portion epitaxially aligned to the buried single crystalline rare earth oxide layer is formed in each of the source trench and the drain trench to form a recessed source and a recessed drain, respectively. Protrusion of the recessed source and recessed drain above the bottom surface of a gate dielectric can be minimized to reduce parasitic capacitive coupling with a gate electrode, while providing low source resistance and drain resistance through the increased thickness of the recessed source and recessed drain relative to the thickness of the top semiconductor layer.

Abstract: A memory device, and a method of forming a memory device, is provided that includes a capacitor with a lower electrode of a metal semiconductor alloy. In one embodiment, the memory device includes a trench present in a semiconductor substrate including a semiconductor on insulating (SOI) layer on top of a buried dielectric layer, wherein the buried dielectric layer is on top of a base semiconductor layer. A capacitor is present in the trench, wherein the capacitor includes a lower electrode of a metal semiconductor alloy having an upper edge that is self-aligned to the upper surface of the base semiconductor layer, a high-k dielectric node layer, and an upper electrode of a metal. The memory device further includes a pass transistor in electrical communication with the capacitor.

Abstract: A dielectric mandrel structure is formed on a single crystalline semiconductor layer. An amorphous semiconductor material layer is deposited on the physically exposed surfaces of the single crystalline semiconductor layer and surfaces of the mandrel structure. Optionally, the amorphous semiconductor material layer can be implanted with at least one different semiconductor material. Solid phase epitaxy is performed on the amorphous semiconductor material layer employing the single crystalline semiconductor layer as a seed layer, thereby forming an epitaxial semiconductor material layer with uniform thickness. Remaining portions of the epitaxial semiconductor material layer are single crystalline semiconductor fins and thickness of these fins are sublithographic. After removal of the dielectric mandrel structure, the single crystalline semiconductor fins can be employed to form a semiconductor device.

Abstract: A method of forming a trench structure that includes forming a metal containing layer on at least the sidewalls of a trench, and forming an undoped semiconductor fill material within the trench. The undoped semiconductor fill material and the metal containing layer are recessed to a first depth within the trench with a first etch. The undoped semiconductor fill material is then recessed to a second depth within the trench that is greater than a first depth with a second etch. The second etch exposes at least a sidewall portion of the metal containing layer. The trench is filled with a doped semiconductor containing material fill, wherein the doped semiconductor material fill is in direct contact with the at least the sidewall portion of the metal containing layer.

Abstract: A method of forming a semiconductor structure, including forming a gate structure on a substrate; performing a first angled implantation on a first side of the gate structure to form a first doped region in the substrate, the first doped region partially extends within a channel of the gate structure and the gate structure blocks the first angled implantation from affecting the substrate on a second side of the gate structure; forming sidewall spacers on sidewalls of the gate; and forming a second doped region in the substrate on the second side of the gate, spaced apart from the channel.

Abstract: A semiconductor structure is provided that includes a material stack including an epitaxially grown semiconductor layer on a base semiconductor layer, a dielectric layer on the epitaxially grown semiconductor layer, and an upper semiconductor layer present on the dielectric layer. A capacitor is present extending from the upper semiconductor layer through the dielectric layer into contact with the epitaxially grown semiconductor layer. The capacitor includes a node dielectric present on the sidewalls of the trench and an upper electrode filling at least a portion of the trench. A substrate contact is present in a contact trench extending from the upper semiconductor layer through the dielectric layer and the epitaxially semiconductor layer to a doped region of the base semiconductor layer. A substrate contact is also provided that contacts the base semiconductor layer through the sidewall of a trench. Methods for forming the above-described structures are also provided.