Abstract: A web support with a high degree of patterning freedom and excellent durability, a production method therefor, and a patterning method. The web support is used when applying a pattern to a nonwoven substance by jetting a high-pressure water stream on a web. The web support production method comprises: a step of preparing a flat metal base material; a step for forming, by etching, a first water conduction hole and second water conduction hole that pass through the front surface of the base material to the back surface, and a recess on the front surface of the base material that includes the first water conduction hole and that corresponds to the pattern; and a step for forming the base material into a cylindrical main body section by welding the edges of the base material to each other.

Abstract: In a method of producing a bonded wafer, the amount of depression of the polishing cloth is 50 ?m to 90 ?m, and the surface hardness (ASKER C) of the polishing cloth is 50 to 60. In the bonded wafer, the polycrystalline silicon layer has a thickness variation ?t of 5% or less, and the support substrate wafer has a GBIR of 0.2 ?m or less and an SFQR of 0.06 ?m or less after the polycrystalline silicon layer is polished.

Abstract: In one embodiment, a substrate treatment apparatus includes a supporter configured to support and rotate a substrate, and a liquid supplier configured to supply a liquid to the substrate. The apparatus further includes a wall provided separately from the supporter and at least partially surrounding the supporter, and a detector provided between the supporter and the wall and configured to detect a change in the liquid.

Abstract: A substrate drying method includes a sublimation-agent-liquid-film placing step of placing a liquid film of a liquid sublimation agent on the front surface of the substrate, a high vapor-pressure liquid supply step of supplying a high vapor-pressure liquid that has vapor pressure higher than the sublimation agent and that does not include water to a rear surface that is a surface on a side opposite to the front surface in the substrate, a vaporizing/cooling step of, after the liquid film of the sublimation agent is placed on the front surface of the substrate, stopping supplying the high vapor-pressure liquid, and, as a result, losing vaporization heat in response to vaporization of the high vapor-pressure liquid, and, as a result, cooling the sublimation agent, and, as a result, solidifying the liquid film of the sublimation agent and a sublimating step of sublimating a sublimation-agent film.

Abstract: Methods of etching an inorganic layer on a glass substrate are described, the methods comprising contacting the glass substrate including an inorganic layer with an etching solution comprising a polar organic solvent and an etchant, wherein the inorganic layer is removed at an inorganic layer etching rate and the glass substrate is etched as a glass etching rate.

Abstract: A substrate supporting apparatus includes a rotatable chuck, a first mass flow controller, a second mass flow controller, a plurality of locating pins and guiding pillars, and a motor in which the rotatable chuck defines a plurality of first injecting ports and second injecting ports, the first injecting ports are connected with a first gas passage for supplying gas to the substrate and sucking the substrate by Bernoulli effect, the second injecting ports are connected with a second gas passage for supplying gas to the substrate and lifting the substrate, the first and the second mass flow controllers are respectively installed on the first and the second gas passages, the plurality of locating pins and guiding pillars are disposed at the top surface of the rotatable chuck and every guiding pillar protrudes to form a holding portion, and the motor is used for rotating the rotatable chuck.

Abstract: A system and method for performing a wet etching process is disclosed. The system includes multiple processing stations accessible by a transfer device, including a measuring station to optically measure the thickness of a substrate, a controller to calculate an etch recipe for the substrate, in real time, and cause a single wafer wet etching station to etch the substrate according to the recipe. In addition, the system can measure the after etch thickness and calculate etch recipes, in real time, as a function of the final measurements of a previous substrate. The system can also include an in situ end point detection device for detecting the TSV reveal point while etching TSVs substrates. The system provides an automated solution to adjust etch recipe parameters in real time according to feedback concerning previously etched wafers and precisely control the TSV reveal height and etch duration using end point detection.

Abstract: A process for edge isolation or texture smoothing of a substrate, in which a process medium which allows control treatment of limited regions of the substrate is used. The process is therefore particularly suitable for one-sided treatment of substrates. The viscosity of the process medium plays a central role here. Furthermore, an apparatus designed for the process is presented.

Abstract: A method for processing a silicon wafer is provided. The method includes allowing an etchant to flow along a surface of the silicon wafer to form a line in which a plurality of apertures are arranged in a flow direction of the etchant from an upstream side to a downstream side. The apertures arranged in the line include a first aperture formed on the most upstream side and a second aperture formed downstream of the first aperture in the flow direction of the etchant. The first aperture and the second aperture are subjected to different processes after being formed.

Abstract: The invention provides a chemical-mechanical polishing composition containing wet-process silica, an oxidizing agent that oxidizes nickel-phosphorous, a chelating agent, polyvinyl alcohol, and water. The invention also provides a method of chemically-mechanically polishing a substrate, especially a nickel-phosphorous substrate, by contacting a substrate with a polishing pad and the chemical-mechanical polishing composition, moving the polishing pad and the polishing composition relative to the substrate, and abrading at least a portion of the substrate to polish the substrate.

Abstract: Processes are described to etch metals. In an embodiment, a process may include contacting a substrate with a stripping solution to remove photoresist from the substrate to produce a stripped substrate. The stripped substrate may include a plurality of solder pillars and a plurality of metal-containing field regions disposed around the plurality of solder pillars. In an illustrative embodiment, the plurality field regions may include copper. Additionally, the process may include rinsing the stripped substrate to produce a rinsed substrate. The rinsed substrate may be substantially free of a Sn layer or a Sn oxide layer. Further, the process may include contacting the rinsed substrate with an etch solution that is capable of removing an amount of one or more metals from the plurality of field regions.

Abstract: A pickling solution for the surface pre-treatment of plastic surfaces in preparation for metallization, the solution comprising a source of Mn(VII) ions; and an inorganic acid; wherein the pickling solution is substantially free of chromium (VI) ions, alkali ions, and alkaline-earth ions.

Abstract: A tool and method is provided for mixing multiple components and feeding a single blend of the multiple components into the tool. The method includes adjusting a concentration of etchant solution. The method includes determining an etch target for each batch of wafers of a plurality of batches of wafers entering an etch chamber of a wafer processing tool. The method further includes adjusting a concentration of 40% NH4F to 49% HF for the each batch of wafers of the plurality of batches of wafers entering the wafer processing tool during a single run.

Abstract: A method for chemical mechanical polishing of a substrate includes polishing the substrate at a stock removal rate of greater than about 2.5 ?/min to achieve a Ra of not greater than about 5.0 ?. The substrate can be a III-V substrate or a SiC substrate. The polishing utilizes a chemical mechanical polishing slurry comprising ultra-dispersed diamonds and at least 80 wt % water.

Abstract: Disclosed are a polishing composition and method of polishing a substrate. The composition has low-load (e.g., up to about 0.1 wt. %) of abrasive particles. The polishing composition also contains water and at least one anionic surfactant. In some embodiments, the abrasive particles are alpha alumina particles (e.g., coated with organic polymer). The polishing composition can be used, e.g., to polish a substrate of weak strength such as an organic polymer. An agent for oxidizing at least one of silicon and organic polymer is included in the composition in some embodiments.

Abstract: Disclosed is a method for polishing a silicon wafer, wherein a surface to be polished of a silicon wafer is rough polished, while supplying a polishing liquid, which is obtained by adding a water-soluble polymer to an aqueous alkaline solution that contains no free abrasive grains, to a polishing cloth. Consequently, the surface to be polished can be polished at high polishing rate and the flatness of the edge portion including roll-off and roll-up can be controlled.

Abstract: The invention relates to a method for making a 3D nanostructure having a nanosubstructure, comprising the steps of: i) providing a mold comprising at least one sharp concave corner; ii) conformational depositing at least one structural material in the sharp concave corner; iii) isotropically removing structural material; iv) depositing at least one other structural material; v) removing earlier deposited structural material; vi) forming a nanosubstructure; and vii) removing the mold thereby providing the 3D nanostructure having the nanosubstructure.

Abstract: The present disclosure relates to roll-to-roll doping method of graphene film, and doped graphene film.

Abstract: A polishing composition for a silicon wafer includes a macromolecular compound, an abrasive, and an aqueous medium. The macromolecular compound includes a constitutional unit (a1) represented by the following general formula (1), a constitutional unit (a2) represented by the following general formula (2), and a constitutional unit (a3) represented by the following general formula (3). The total of the constitutional unit (a3) is 0.001 to 1.5 mol % of all the constitutional units of the macromolecular compound.

Abstract: Provided are a metal-polishing liquid that comprises an oxidizing agent, an oxidized-metal etchant, a protective film-forming agent, a dissolution promoter for the protective film-forming agent, and water; a method for producing it; and a polishing method of using it. Also provided are materials for the metal-polishing liquid, which include an oxidized-metal etchant, a protective film-forming agent, and a dissolution promoter for the protective film-forming agent.

Abstract: The CMP polishing liquid of the present invention contains 1,2,4-triazole, a phosphoric acid, an oxidant, and abrasive particles. The polishing method of the present invention is a substrate polishing method for polishing a substrate with a polishing cloth while supplying a CMP polishing liquid between the substrate and the polishing cloth, in which the substrate is a substrate having a palladium layer, and the CMP polishing liquid is a CMP polishing liquid containing 1,2,4-triazole, a phosphoric acid, an oxidant, and abrasive particles.

Abstract: A substrate processing apparatus comprising a substrate holding rotating mechanism, a process liquid supply mechanism having a nozzle for dispensing a process liquid toward a principal face of the substrate, a processing liquid reservoir for holding sufficient process liquid to form a liquid film covering the whole principal face of the substrate, a liquid film forming unit for forming the liquid film by supplying the process liquid onto the principal face of the substrate in a single burst, and a control unit for controlling the liquid film forming unit and the process liquid supply mechanism such that the process liquid is dispensed from the process liquid nozzle toward the principal face of the substrate after formation of the liquid film covering the whole area of the principal face of the substrate by the liquid film forming unit.

Abstract: Greater planarity is achieved between surfaces of a conductive structure and a layer within which the conductive structure resides. A portion of the conductive structure protruding above the surface of the layer is selectively oxidized, at least in part, to form an oxidized portion. The oxidized portion is then removed, at least partially, to facilitate achieving greater planarity. The protruding portions may optionally be formed by selectively disposing conductive material over the conductive structure, when that the conductive structure is initially recessed below the surface of the layer. A further embodiment includes selectively oxidizing a portion of the conductive structure below the surface of the layer, removing at least some of the oxidized portion so that an upper surface of the conductive structure is below the upper surface of the layer, and planarizing the upper surface of the layer to the upper surface of the conductive structure.

Abstract: In accordance with an embodiment of the present invention, a method of polishing a device includes providing a layer having a non-uniform top surface. The non-uniform top surface includes a plurality of protrusions. The method further includes removing the plurality of protrusions by exposing the layer to a fluid that has gas bubbles and a liquid.

Abstract: A substrate edge bevel etch module for etching a material from a peripheral edge of a substrate with an etchant is described. The substrate edge bevel etch module includes a rotatable substrate holder having a support for a substrate, and a surface tension etch applicator comprising a wetted etching surface opposing a substrate surface proximate an edge of the substrate when the surface tension etch applicator is located proximate to the edge of the substrate. The surface tension etch applicator further includes an etchant dispensing portion, proximate the wetted etching surface, which dispenses an etchant in a region between the wetted etching surface and the substrate surface and wet at least a portion of the wetted etching surface and the substrate surface. A spacing between the wetted etching surface and the substrate surface is selected to retain the etchant using surface tension forces and form a meniscus there between.

Abstract: A method for making a printed wiring member including wire-bondable contact pads and wear-resistant connector pads, the method includes the steps of a) providing a blank printed wiring member comprising a copper foil laminated to a dielectric substrate; b) masking the blank printed wiring member to protect regions of the copper foil; c) removing copper in unprotected regions of the blank printed wiring member to form a patterned printed wiring member including contact pads and connector pads; d) depositing a nickel coating on the patterned printed wiring member using an electroless nickel deposition process; e) depositing a gold layer on the nickel coating using an electroless gold deposition process; and f) depositing palladium on the gold layer using an electroless palladium deposition process to improve wear resistance of the connector pads while preserving bondability of the contact pads.

Abstract: A method for manufacturing a glass substrate for a magnetic disk comprises a surface grinding step of processing a mirror-surface plate glass, having a main surface in the form of a mirror surface, to a required flatness and surface roughness using fixed abrasive particles. The method comprises, before the surface grinding step using the fixed abrasive particles, a surface roughening step of roughening the surface of the mirror-surface plate glass by frosting.

Abstract: A method of depositing a non-continuous coating of a first material on a substrate, comprising: a) the formation of a mask on this substrate, by forming at least two mask layers, and etching of at least one cavity in these layers, this cavity having an outline such that a coating, deposited on the substrate, through the cavities of the mask, has at least one discontinuity over said outline of the cavity; b) the deposition of the first material on the substrate, through the cavities of the mask, the coating thus deposited having at least one discontinuity over the outline of said cavity; and c) the mask is removed.

Abstract: An apparatus for altering a surface of a cylindrical object includes at least one container containing a fluid resist therein and having at least one opening from which the fluid resist is discharged; at least one roller operatively associated with the at least one container and having a surface sized and shaped to be exposed to the at least one opening, the surface area including a pattern of shapes and upon which the fluid resist is deposited; and at least one support member adjacent the at least one roller for supporting the cylindrical object during transit for contacting the at least one roller. A method is also provided.

Abstract: Compositions useful for the selective removal of silicon nitride materials relative to poly-silicon, silicon oxide materials and/or silicide materials from a microelectronic device having same thereon. The removal compositions include fluorosilicic acid, silicic acid, and at least one organic solvent. Typical process temperatures are less than about 100° C. and typical selectivity for nitride versus oxide etch is about 200:1 to about 2000:1. Under typical process conditions, nickel-based silicides as well as titanium and tantalum nitrides are largely unaffected, and polysilicon etch rates are less than about 1 ? min?1.

Abstract: A composition and a method for chemical mechanical polishing. The composition includes a surfactant anion an alkyl alcohol, a controlled amount of chloride ion source and a diluent. The composition further includes abrasive particles and an oxidizer. The method includes providing the composition on a surface to be polished and polishing the surface by contacting the surface with a polishing pad.

Abstract: Mirror-polishing a front surface of a silicon wafer using polishing liquid composed of an abrasive grain-free alkaline solution including water-soluble polymers simplifies a polishing process, thus leading to an increase in productivity and a reduction in cost, and reduces the density of LPDs attributable to processing and occurring in the front surface of a mirror-polished wafer, thus improving the surface roughness of the wafer front surface.

Abstract: According to one embodiment, a method is disclosed for chemical planarization. The method can include forming a surface layer on a to-be-processed film having irregularity. The surface layer binds to or adsorbs onto the to-be-processed film along the irregularity to suppress dissolution of the to-be-processed film. The method can include planarizing the to-be-processed film in a processing solution dissolving the to-be-processed film, by rotating the to-be-processed film and a processing body while the to-be-processed film contacting the processing body via the surface layer, removing the surface layer on convex portions of the irregularity while leaving the surface layer on concave portions of the irregularity and making dissolution degree of the convex portions larger than dissolution degree of the concave portions.

Abstract: A polishing apparatus is used for polishing and planarizing a substrate such as a semiconductor wafer on which a conductive film such as a copper (Cu) layer or a tungsten (W) layer is formed. The polishing apparatus includes a polishing table having a polishing surface, a motor for rotating the polishing table, a top ring for holding a substrate and pressing the substrate against the polishing surface, a film thickness measuring sensor disposed in the polishing table for scanning a surface of the substrate, and a computing device for processing signals of the film thickness measuring sensor to compute a film thickness of the substrate.

Abstract: In a method for the treatment of a substrate surface of a flat substrate with a process medium at the substrate underside, the process medium has a removing or etching effect on the substrate surface. The substrates are wetted with the process medium from below in a manner lying horizontally. The upwardly facing substrate top side is wetted or covered with water or a corresponding protective liquid over a large area or over the whole area as protection against the process medium acting on the substrate top side.

Abstract: A method of producing images on a metalized substrate is described. The metalized substrate comprises a substrate having a top side and a bottom side and a metalized coating adhered to the top side of the substrate. The method comprises the steps of printing an image onto the metalized coating by selectively applying a protective coating of the image, curing the protective coating, applying a demetalizing solution onto the metalized substrate, rinsing the metalized substrate, drying the metalized substrate, applying an adhesive coating onto the metalized substrate, and removing the adhesive coating.

Abstract: A coating device includes a coating mechanism which includes nozzles for ejecting a liquid material onto front and rear surfaces of a substrate while rotating the substrate; and an adjusting mechanism which adjusts the coating state of the liquid material at the outer periphery of the substrate; wherein the adjusting mechanism includes a dip portion which dips the outer periphery of the substrate in a solution while rotating the substrate and dissolves; and a suction portion which suctions the vicinity of the outer periphery of the substrate after dipping in the solution.

Abstract: A coating device includes a coating mechanism which includes nozzles for ejecting a liquid material onto front and rear surfaces of a substrate while rotating the substrate; and an adjusting mechanism which adjusts the coating state of the liquid material at the outer periphery of the substrate; wherein the adjusting mechanism includes a dip portion which dips the outer periphery of the substrate in a solution while rotating the substrate and dissolves and removes a thin film formed on the outer periphery of the substrate; and a suction portion which suctions the vicinity of the outer periphery of the substrate after dipping in the solution.

Abstract: A method for chemically treating a disc-shaped substrate having a bottom surface, a top surface and side surfaces by contacting a process medium that is fluid-chemically active with at least the bottom surface of the substrate. The substrate is moved relative to the process medium while forming a triple line between the substrate, the substrate medium and the atmosphere surrounding the substrate and medium. In order to chemically remove errors, particularly in the side surfaces, relative motion should be carried out while avoiding a contacting of the process medium with the top surface of the substrate, where the triple line is formed at a desired height of the side surface facing away from the process medium flow side in relation to the relative motion between the substrate and the process medium.

Abstract: In etching processing of silicon, in particular anisotropic etching processing of silicon in a manufacturing step of MEMS parts, an etching liquid having a long life of etching liquid and an etching method are provided by suppressing a lowering of an etching rate at the time of warming which is characteristic of a hydroxylamine-containing etching liquid. A silicon etching liquid which is an alkaline aqueous solution containing an alkali metal hydroxide, hydroxylamine and an inorganic carbonate compound and having a pH of 12 or more and which is able to anisotropically dissolve monocrystalline silicon therein, and an etching method of silicon using this etching liquid are provided.

Abstract: The invention provides a chemical-mechanical polishing composition comprising alpha alumina, fumed alumina, silica, an oxidizing agent that oxidizes nickel-phosphorous, oxalic acid, optionally, tartaric acid, optionally, a nonionic surfactant, optionally, a biocide, and water. The invention also provides a method of chemically-mechanically polishing a substrate comprising contacting a substrate with a polishing pad and the chemical-mechanical polishing composition, moving the polishing pad and the polishing composition relative to the substrate, and abrading at least a portion of the substrate to polish the substrate.

Abstract: A polishing slurry includes an abrasive, a dispersion agent, a polish accelerating agent and an adhesion inhibitor. The adhesion inhibitor includes a benzene compound combined with a carboxyl group. Methods of planarizing an insulating layer using the slurry are also provided.

Abstract: In a substrate processing method according to the present invention, a cleaning liquid nozzle supplies a rinsing liquid to a central portion of a substrate and thereafter moves from a position corresponding to the central portion of the substrate to a position corresponding to a peripheral, edge portion thereof while supplying the rinsing liquid before stopping at the position corresponding to the peripheral edge portion. Next, a drying liquid nozzle moves from the position corresponding to the peripheral edge portion to the position corresponding to the central portion while supplying a drying liquid. Then, the drying liquid nozzle is kept stationary at the position corresponding to the central portion for a predetermined period of time while supplying the drying liquid. Thereafter, a gas nozzle moves from the position corresponding to the central portion to the position corresponding to the peripheral edge portion while supplying an inert gas.

Abstract: The present invention provides a polishing composition that can be suitably used in polishing of polysilicon, and a polishing method using the polishing composition. The polishing composition contains abrasive grains and an anionic surfactant having a monooxyethylene group or a polyoxyethylene group and has a pH of 9 to 12. If the anionic surfactant contained in the polishing composition has a polyoxyethylene group, the number of repeating oxyethylene units in the polyoxyethylene group is preferably 2 to 8. The anionic surfactant contained in the polishing composition can be an anionic surfactant that has a phosphate group, a carboxy group, or a sulfo group as well as a monooxyethylene group or a polyoxyethylene group. The content of the anionic surfactant in the polishing composition is preferably 20 to 500 ppm.

Abstract: A method for patterning an article, the article comprising a first layer of a first material, the method comprising providing a thread carrying a first species, e.g. a solvent in which the first material is soluble, and contacting the thread with the first layer to remove at least part of the first layer.

Abstract: A method for processing a semiconductor wafer includes bringing at least one grinding tool in contact with the semiconductor wafer; removing material from the semiconductor wafer using the grinding tool; disposing a liquid medium having a viscosity of at least 3×10?3 N/m2·s and at most 100×10?3 N/m2·s between the at least one grinding tool and the semiconductor wafer; and separating the at least one grinding tool and the semiconductor wafer so as to end the processing.

Abstract: An object of the present invention is to provide a method for etching a single wafer, which effectively realizes a high flatness of wafer and an increase in productivity thereof. In a method for etching a single wafer, a single thin disk-like wafer sliced from a silicon single crystal ingot is spun, and a front surface of the wafer is etched with an etching solution supplied thereto. In the method, a plurality of supply nozzles are disposed above and opposite to the front surface of the wafer at different portions in the radial direction of the wafer, respectively; and then one or more conditions selected from the group consisting of temperatures, kinds, and supply flow rates of etching solutions from the plurality of supply nozzles are changed.

Abstract: Methods and apparatus for reducing damage of a semiconductor donor wafer include the steps of: (a) rotating a polishing pad, rotating the semiconductor donor wafer, applying a polishing slurry to the polishing pad, and pressing the semiconductor donor wafer and the polishing pad together; and (b) rotating the polishing pad and the semiconductor donor wafer, discontinuing the application of the polishing slurry, applying a rinsing fluid to the polishing pad, and pressing the semiconductor donor wafer and the polishing pad together, wherein step (a) followed by step (b) is carried out in sequence at least two times, and at least one of the following are reduced in at least two successive intervals of step (a): (i) a pressure at which the semiconductor donor wafer and the polishing pad are pressed together, (ii) a mean particle size of an abrasive within the polishing slurry, and (iii) a concentration of the slurry in water and stabilizers.

Abstract: A method for producing a semiconductor wafer includes a number of steps in order including a bilateral material-removing process followed by rounding off an edge of the wafer and grinding front and back sides of the wafer by holding one side and grinding the other. The front and back arc then polished with a polishing cloth including bound abrasives and subsequently treated with an etching medium to carry out a material removal of no more than 1 ?m on each side. The front side is then polished using a polishing cloth including bound abrasives and the back side is simultaneously polished using a polishing cloth free of abrasives while a polish with abrasives is provided. The edge is then polished followed by polishing the back with a polishing cloth including bound abrasives and simultaneously polishing the front with a cloth free of abrasives while a polish including abrasives is provided.

Abstract: Exemplary embodiments provide methods for planarizing a semiconductor surface. In embodiments, the disclosed planarizing methods can include a chemical mechanical planarization (CMP) process using a slurry-free solution that includes hydrogen peroxide (H2O2) but is free of particles such as oxide particles. A semiconductor surface (e.g., germanium) can then be planarized to provide a desirable surface roughness. In embodiments, high-quality Group III-V materials can be formed on the planarized semiconductor surface.