Abstract: A slurry is described that comprises a mixture of between about 0.01 mole and about 0.1 mole per liter of an organic acid salt, between about 1% to about 20% by volume of an abrasive, and an oxidizer.

Abstract: A Ta barrier slurry for Chemical-Mechanical Polishing (CMP) during copper metallization contains an organic additive which suppresses formation of precipitates and copper staining. The organic additive is chosen from a class of compounds which form multiple strong adsorbant bonds to the surface of silica or copper, which provide a high degree of surface coverage onto the reactive species, thereby occupying potential reaction sites, and which are sized to sterically hinder the collisions between two reactant molecules which result in new bond formation. The organic additive-containing slurry cain be utilized throughout the entire polish time. Alternatively, a slurry not containing the organic additive can be utilized for a first portion of the polish, and a slurry containing the organic additive or a polishing solution containing the organic additive can be utilized for a second portion of the polish.

Abstract: A method of producing a metastable degradation resistant amorphous hydrogenated silicon film is provided, which comprises the steps of growing a hydrogenated amorphous silicon film, the film having an exposed surface, illuminating the surface using an essentially blue or ultraviolet light to form high densities of a light induced defect near the surface, and etching the surface to remove the defect.

Abstract: The nanometer-gate MOSFET device of the present invention comprises a shallow-trench-isolation structure; a pair of second conductive sidewall spacers being formed over each inner sidewall of a gate region and on a portion of a first conductive layer and a first raised field-oxide layers for forming an implant region in a central portion of a channel; a buffer-oxide layer being formed over each sidewall of the gate region for forming lightly-doped source/drain diffusion regions; a first sidewall dielectric spacer being formed over each sidewall of the buffer-oxide layers for forming heavily-doped source/drain diffusion regions; a second sidewall dielectric spacer being formed over each sidewall of the first sidewall dielectric spacers for forming a metal-silicide layer over each of heavily-doped source/drain diffusion regions; and a highly conductive-gate structure being formed in the gate region.

Abstract: A method of forming MIM capacitor top (16) and bottom (12) plates, using a first and second resist (18/20) and a single RIE process. A first conductive layer (12) is deposited over a substrate (10). An insulating layer (14) is deposited over the first conductive layer (12). A second conductive layer (16) is deposited over the insulating layer (14). A first resist (18) is deposited over the second conductive layer (16), and the first resist (18) is patterned. A second resist (20) is deposited over the first resist (18) and patterned. The first and second resist (18/20) patterns are simultaneously transferred to the first and second conductive layers (12) and (16), respectively, by exposure to a single reactive ion etch (RIE) process.

Abstract: Non-chromate solutions for treating and/or etching metals, particularly, aluminum, aluminum alloys, steel and titanium, and method of applying same wherein the solutions include either a titanate or titanium dioxide as a “drop-in replacement” for a chromium-containing compound in a metal surface etching solution that otherwise would contain chromium.

Abstract: A high density plasma deposition process for eliminating or reducing a zipper-like profile of opened-up voids in a poly trench fill by controlling separation between a transfer gate and storage node in a vertical DRAM, comprising: etching a recess or trench into poly Si of a semiconductor chip; forming a pattern of SiN liner using a mask transfer process for formation of a single sided strap design; removing the SiN liner and etching adjacent collar oxide away from a top part of the trench; depositing a high density plasma (HDP) polysilicon layer in the trench by flowing either SiH4 or SiH4+H2 in an inert ambient; employing a photoresist in the trench and removing the high density plasma polysilicon layer from a top surface of the semiconductor to avoid shorting in the gate conductor either by spinning on resist and subsequent chemical mechanical polishing or chemical mechanical downstream etchback of the polysilicon layer; and stripping the photoresist and depositing a top trench oxide by high den

Abstract: A composition suitable for cleaning and methods of cleaning etch residue are provided. The composition includes at least one source of a fluoride ion and at least one organic solvent.

Abstract: A method of forming a shallow trench within a trench capacitor structure. This method can be used, for example, in the construction of a DRAM device.

Abstract: A method of forming a buried plate in a silicon substrate uses a silicon substrate having a deep trench etched into the silicon substrate. A highly doped polysilicon layer is formed within the trench. A nitride layer is then formed within the trench over the polysilicon layer. After forming both the polysilicon layer and the nitride layer, both the polysilicon layer and the nitride layer are etched from a certain uppermost portion of the sidewalls of the trench thereby exposing the silicon substrate at the uppermost portions of the sidewalls. After exposing the silicon substrate at the uppermost portions of the sidewalls, a collar oxide layer is formed over the exposed silicon substrate at the uppermost portions of the sidewalls thereby protecting any edges of the polysilicon layer exposed by the etching step.

Abstract: The process comprises the steps of forming, on top of a semiconductor material wafer, a holed mask having a lattice structure and comprising a plurality of openings each having a substantially square shape and a side with an inclination of 45° with respect to the flat of the wafer; carrying out an anisotropic etch in TMAH of the wafer, using said holed mask, thus forming a cavity, the cross section of which has the shape of an upside-down isosceles trapezium; and carrying out a chemical vapor deposition using TEOS, thus forming a TEOS layer which completely closes the openings of the holed mask and defines a diaphragm overlying the cavity and on which a suspended integrated structure can subsequently be manufactured.

Abstract: A pixel electrode employs a transparent electrode made from indium-zinc-oxide (IZO) that is capable of preventing damage and bending thereof. In a liquid crystal display device containing pixel electrodes, the transparent electrode is made from indium-zinc-oxide (IZO) having an amorphous structure so that it can be etched within a short period of time with a low concentration of etchant. Accordingly, it is possible to prevent damage and bending of the transparent electrode upon the patterning thereof.

Abstract: An optical element comprising at least a plurality of pixels formed on a substrate and partition walls arranged respectively between adjacent pixels is manufactured by a method comprising steps of forming partition walls of a resin composition on a substrate, performing a dry etching process by irradiating the substrate carrying the partition walls formed thereon with plasma in an atmosphere containing gas selected from oxygen, argon and helium, performing a plasma treatment process by irradiating the substrate subjected to the dry etching process with plasma in an atmosphere containing at least fluorine atoms, and forming pixels by applying ink to the areas surrounded by the partition walls by means of an ink-jet system.

Abstract: There is provided a method of optimizing recipe of in-situ cleaning process for process chamber after a specific process on semiconductor wafers by using Residual Gas Analyzer Quadrupole Mass Spectrometer (RGA-QMS) According to the present invention, a Chemical Vapor Deposition (CVD) apparatus for manufacturing semiconductor devices comprises: a process chamber; process gas supply line for supplying process gas into the process chamber; a waste-gas exhaust line for removing the waste-gas from the process chamber after process; a supply line for supplying a ClF3 gas into the process chamber; a sampling manifold for sampling the gas inside process chamber by using pressure difference; and RGA-QMS for analyzing the sampling gas, and the optimization of the end points according to gas flow, pressure, and temperature of the cleaning process for the process chamber is achieved through the analysis by above RGA-QMS.

Abstract: A novel method to remove residual toxic gases trapped by a polymerizing process by an inert ion sputter is described. A masking layer is formed overlying a semiconductor substrate. An opening is etched through the masking layer into the semiconductor substrate whereby a polymer forms on sidewalls of the opening and whereby residual toxic gas reactants from gases used in the etching step are adsorbed by the polymer. Thereafter, the polymer is sputtered with non-reactive ions whereby the residual toxic gas reactants are desorbed from the polymer to complete removal of residual toxic gas reactants in the fabrication of an integrated circuit device.

Abstract: A method and a solution for preparing SEM samples comprising low-K dielectric materials. The process begins by providing a SEM sample comprising low-K dielectric material and silicon oxide material. A solution is formed for preparing (staining and etching) the SEM sample by adding NH4F (s) to a solution comprising CH3COOH having a concentration of about 98% at a ratio of about 1 g NH4F (s):20 ml CH3COOH, then stirring until the NH4F (s) is thoroughly dissolved. Alternatively, the NH4F (s) can be added to a solution comprising HNO3 having a concentration of about 70% and CH3COOH having a concentration of about 98%, with a volume ratio of about 15 ml HNO3:20 ml CH3COOH. The NH4F (s) is added at a ratio of about 1 g NH4F (s):35 ml CH3COOH and HNO3, and stirred until the NH4F (s) is thoroughly dissolved. The SEM sample is then etched in this solution for about 3 seconds, whereby the low-K dielectric material and silicon oxide material have similar etch rates with good selectivity to metals.

Abstract: The invention provides a method for etching silicon nitride selective to titanium silicide and fabricating multi-level contact openings on a quartermicron device using a two step etch process. The process begins by providing a substrate having thereover a silicon nitride hard mask at one level and a titanium silicide layer at another level wherein the silicon nitride hard mask and the titanium silicide region have an oxide layer thereover. In a first etch step, the oxide layer is patterned to form a first contact opening and a second contact opening. The first contact opening stops on the silicon nitride hard mask and the second contact opening stops on the titanium silicide region. In a second etch step the silicon nitride hard mask is etched through in the first contact opening using an etch selective to titanium silicide. The etch comprises CH2F2 and O2 at a ratio of CH2F2 to O2 of between about 2 and 4.

Abstract: A method for fabricating a nano-sized diamond whisker includes the steps of depositing a diamond film on a substrate, forming a nano-sized mask pattern on the deposited diamond film, and etching the diamond film by using the nano-sized pattern as an etching mask. The nano-sized diamond whisker can be used as a new field emission cold cathode device, thereby advancing a practical use of a field emission device having high performance, and can also be applied to various fields such as a new composite material and a mechanical device.

Abstract: Processes for forming trenches within silicon substrates are described. According to an embodiment of the invention, a masked substrate is initially provided that comprises (a) a silicon substrate and (b) a patterned resist layer over the silicon substrate. The patterned resist layer has one or more apertures formed therein. Subsequently, a trench is formed in the substrate through the apertures in the resist layer by an inductive plasma-etching step, which is conducted using plasma source gases that comprise SF6, at least one fluorocarbon gas, and N2. If desired, Cl2 can also be provided in addition to the above source gases. The process of the present invention produces chamber deposits in low amounts, while providing high etching rates, high silicon:resist selectivities, and good trench sidewall profile control.

Abstract: Copper or a copper alloy is removed by chemical-mechanical planarization (CMP) in a slurry of an oxidizer, an oxidation inhibitor, and an additive that appreciably regulates copper complexing with the oxidation inhibitor.