Abstract: The invention relates generally to a method for fabricating oxygen-implanted semiconductors, and more particularly to a method for fabricating oxygen-implanted silicon-on-insulation (“SOI”) type semiconductors by cutting-up regions into device-sized pieces prior to the SOI-oxidation process. The process sequence to make SOI is modified so that the implant dose may be reduced and relatively long and high temperature annealing process steps may be shortened or eliminated. This simplification may be achieved if, after oxygen implant, the wafer structure is sent to pad formation, and masking and etching. After the etching, annealing or oxidation process steps may be performed to create the SOI wafer.

Abstract: A method for forming a borderless contact for a semiconductor FET (Field Effect Transistor) device, the method comprising, forming a gate conductor stack on a substrate, forming spacers on the substrate, such that the spacers and the gate conductor stack partially define a volume above the gate conductor stack, wherein the spacers are sized to define the volume such that a stress liner layer deposited on the gate conductor stack substantially fills the volume, depositing a liner layer on the substrate, the spacers, and the gate conductor stack, depositing a dielectric layer on the liner layer, etching to form a contact hole in the dielectric layer, etching to form the contact hole in the liner layer, such that a portion of a source/drain diffusion area formed in the substrate is exposed and depositing contact metal in the contact hole.

Abstract: An immersion lithography system is provided which includes an optical source operable to produce light having a nominal wavelength and an optical imaging system. The optical imaging system has an optical element in an optical path from the optical source to an article to be patterned thereby. The optical element has a face which is adapted to contact a liquid occupying a space between the face and the article. The optical element includes a material which is degradable by the liquid and a protective coating which covers the degradable material at the face for protecting the face from the liquid, the protective coating being transparent to the light, stable when exposed to the light and stable when exposed to the liquid.

Abstract: A method of fabricating a structure and fabricating related semiconductor transistors and novel semiconductor transistor structures. The method of fabricating the structure includes: providing a substrate having a top surface; forming an island on the top surface of the substrate, a top surface of the island parallel to the top surface of the substrate, a sidewall of the island extending between the top surface of the island and the top surface of the substrate; forming a plurality of carbon nanotubes on the sidewall of the island; and performing an ion implantation, the ion implantation penetrating into the island and blocked from penetrating into the substrate in regions of the substrate masked by the island and the carbon nanotubes.

Abstract: Methods of forming a conductive element for an integrated circuit (IC) chip and a related structure are disclosed. One embodiment of the method may include forming a first sacrificial layer having a pattern therein for a first dielectric layer to surround the conductive element; forming the first dielectric layer within the patterned first sacrificial layer; removing the patterned first sacrificial layer, leaving the first dielectric layer; and forming the conductive element in a space vacated by the patterned first sacrificial layer. The methods prevent damage caused to low dielectric constant dielectric layers during etching and stripping/cleaning processes.

Abstract: A trench-type storage device includes a trench in a substrate (100), with bundles of carbon nanotubes (202) lining the trench and a trench conductor (300) filling the trench. A trench dielectric (200) may be formed between the carbon nanotubes and the sidewall of the trench. The bundles of carbon nanotubes form an open cylinder structure lining the trench. The device is formed by providing a carbon nanotube catalyst structure on the substrate and patterning the trench in the substrate; the carbon nanotubes are then grown down into the trench to line the trench with the carbon nanotube bundles, after which the trench is filled with the trench conductor.

Abstract: A memory cell in an integrated circuit is fabricated in part by forming a lower electrode feature, an island, a sacrificial feature, a gate feature, and a phase change feature. The island is formed on the lower electrode feature and has one or more sidewalls. It comprises a lower doped feature, a middle doped feature formed above the lower doped feature, and an upper doped feature formed above the middle doped feature. The sacrificial feature is formed above the island, while the gate feature is formed along each sidewall of the island. The gate feature overlies at least a portion of the middle doped feature of the island and is operative to control an electrical resistance therein. Finally, the phase feature is formed above the island at least in part by replacing at least a portion of the sacrificial feature with a phase change material. The phase change material is operative to switch between lower and higher electrical resistance states in response to an application of an electrical signal.

Abstract: A carbon nanotube filter, a use for a carbon nanotube filter and a method of forming a carbon nanotube filter. The method including (a) providing a carbon source and a carbon nanotube catalyst; (b) growing carbon nanotubes by reacting the carbon source with the nanotube catalyst; (c) forming chemically active carbon nanotubes by forming a chemically active layer on the carbon nanotubes or forming chemically reactive groups on sidewalls of the carbon nanotubes; and (d) placing the chemically active nanotubes in a filter housing.

Abstract: A carbon nanotube filter. The filter including a filter housing; and chemically active carbon nanotubes within the filter housing, the chemically active carbon nanotubes comprising a chemically active layer formed on carbon nanotubes or comprising chemically reactive groups on sidewalls of the carbon nanotubes; and media containing the chemically active carbon nanotubes.

Abstract: An exposure system for exposing a photoresist layer on a top surface of a wafer to light. The exposure system including: an environment chamber containing a light source, one or more focusing lenses, a mask holder, a slit and a wafer stage, the light source, all aligned to an optical axis, the wafer stage moveable in two different orthogonal directions orthogonal to the optical axis, the mask holder and the slit moveable in one of the two orthogonal directions; a filter in a sidewall of the environment chamber, the filter including: a filter housing containing chemically active carbon nanotubes, the chemically active carbon nanotubes comprising a chemically active layer formed on carbon nanotubes or comprising chemically reactive groups on sidewalls of the carbon nanotubes; and means for forcing air or inert gas first through the filter then into the environment chamber and then out of the environment chamber.

Abstract: A sidewall image transfer process for forming sub-lithographic structures employs a layer of sacrificial material that is deposited over a structure layer and covered by a cover layer. The sacrificial material layer and the cover layer are patterned with conventional resist and etched to form a sacrificial mandrel. The edges of the mandrel are oxidized or nitrided in a plasma at low temperature, after which the material layer and the cover layer are stripped, leaving sublithographic sidewalls. The sidewalls are used as hardmasks to etch sublithographic gate structures in the gate conductor layer.

Abstract: A carbon nanotube filter, a use for a carbon nanotube filter and a method of forming a carbon nanotube filter. The method including (a) providing a carbon source and a carbon nanotube catalyst; (b) growing carbon nanotubes by reacting the carbon source with the nanotube catalyst; (c) forming chemically active carbon nanotubes by forming a chemically active layer on the carbon nanotubes or forming chemically reactive groups on sidewalls of the carbon nanotubes; and (d) placing the chemically active nanotubes in a filter housing.

Abstract: A carbon nanotube filter, a use for a carbon nanotube filter and a method of forming a carbon nanotube filter. The method including (a) providing a carbon source and a carbon nanotube catalyst; (b) growing carbon nanotubes by reacting the carbon source with the nanotube catalyst; (c) forming chemically active carbon nanotubes by forming a chemically active layer on the carbon nanotubes or forming chemically reactive groups on sidewalls of the carbon nanotubes; and (d) placing the chemically active nanotubes in a filter housing.

Abstract: An air particle precipitator and a method of air filtration comprise a housing unit; a first conductor in the housing unit; a second conductor in the housing unit; and a carbon nanotube grown on the second conductor. Preferably, the first conductor is positioned opposite to the second conductor. The air particle precipitator further comprises an electric field source adapted to apply an electric field to the housing unit. Moreover, the carbon nanotube is adapted to ionize gas in the housing unit, wherein the ionized gas charges gas particulates located in the housing unit, and wherein the first conductor is adapted to trap the charged gas particulates. The air particle precipitator may further comprise a metal layer over the carbon nanotube.

Abstract: A sidewall image transfer process for forming sub-lithographic structures employs a layer of sacrificial polymer containing silicon that is deposited over a gate conductor layer and covered by a cover layer. The sacrificial polymer layer is patterned with conventional resist and etched to form a sacrificial mandrel. The edges of the mandrel are oxidized or nitrided in a plasma at low temperature, after which the polymer and the cover layer are stripped, leaving sublithographic sidewalls. The sidewalls are used as hardmasks to etch sublithographic gate structures in the gate conductor layer.

Abstract: A method of selectively forming a germanium structure within semiconductor manufacturing processes removes the native oxide from a nitride surface in a chemical oxide removal (COR) process and then exposes the heated nitride and oxide surface to a heated germanium containing gas to selectively form germanium only on the nitride surface but not the oxide surface.

Abstract: An immersion lithography system is provided which includes an optical source operable to produce light having a nominal wavelength and an optical imaging system. The optical imaging system has an optical element in an optical path from the optical source to an article to be patterned thereby. The optical element has a face which is adapted to contact a liquid occupying a space between the face and the article. The optical element includes a material which is degradable by the liquid and a protective coating which covers the degradable material at the face for protecting the face from the liquid, the protective coating being transparent to the light, stable when exposed to the light and stable when exposed to the liquid.

Abstract: Methods of forming a gas dielectric and a related structure are disclosed. In one embodiment, the method includes providing a wiring level including at least one conductive portion within a sacrificial dielectric; forming a nanofiber layer over the wiring level; vaporizing the sacrificial dielectric by heating; evacuating the vaporized sacrificial layer; and sealing pores in the nanofiber layer.

Abstract: Techniques for semiconductor processing are provided. In one aspect, a method for patterning one or more features in a semiconductor device comprises the following step. At least one critical dimension of the one or more features is reduced during etching of the antireflective material. A lithographic structure is also provided.

Abstract: Disclosed are a semiconductor structure and a method that allow for simultaneous voltage/current conditioning of multiple memory elements in a nonvolatile memory device with multiple memory cells. The structure and method incorporate the use of a resistor connected in series with the memory elements to limit current passing through the memory elements. Specifically, the method and structure incorporate a blanket temporary series resistor on the wafer surface above the memory cells and/or permanent series resistors within the memory cells. During the conditioning process, these resistors protect the transition metal oxide in the individual memory elements from damage (i.e., burn-out), once it has been conditioned.