Abstract: The invention relates to a method for dry chemical treatment of substrates selected from the group comprising silicon, ceramic, glass, and quartz glass, in which the substrate is treated in a heated reaction chamber with a gas which contains hydrogen chloride as etching agent, and also to a substrate which can be produced in this way. The invention likewise relates to uses of the previously mentioned method.

Abstract: A method of manufacturing touch screen panels includes forming a photoresist film on a first surface of a substrate having high transmittance, removing the photoresist film in regions between unit cells by utilizing exposing and developing processes, etching the substrate in the regions where the photoresist film has been removed, removing the photoresist film from the substrate after the etching, performing a tempering process on the substrate including the etched regions, forming touch screen panels at the unit cells defined by the etched regions on the first surface of the substrate, and cutting the substrate at the etched regions to separate the touch screen panels.

Abstract: The present invention involves the use of random copolymer top coats that can be spin coated onto block copolymer thin films and used to control the interfacial energy of the top coat-block copolymer interface. The top coats are soluble in aqueous weak base and can change surface energy once they are deposited onto the block copolymer thin film. The use of self-assembled block copolymers to produce advanced lithographic patterns relies on their orientation control in thin films. Top coats potentially allow for the facile orientation control of block copolymers which would otherwise be quite challenging.

Abstract: The present invention provides an ink jet print head having a channel shape that meets an intended purpose, and a method for manufacturing the ink jet print head. In the method for manufacturing the ink jet print head, an SIO SOI substrate is prepared which has a first silicon layer, a second silicon layer, and an insulating layer. A sacrifice layer is formed on the first monocrystal silicon layer. An etching stop layer is formed over the sacrifice layer. An energy generating element is formed on a surface of the SOI substrate. Etching is performed on the second silicon layer and the insulating layer to form an ink supply port. The supply port is formed by etching. The first silicon layer is etched to form a liquid channel. A part of the etching stop layer is removed to form an ejection port.

Abstract: In a through hole closing process, a metal plate is attached to one surface of a conductive base member having a plurality of through holes by the use of a magnet, in a copper plating process, a copper plating layer is formed on the conductive base member and the metal plate exposed within the through holes, from the side of the conductive base member where the metal plate is not attached, thereby to fill up the through holes, in a film forming process, a Pd alloy film is formed by plating on the surface of the conductive base member after removal of the metal plate, and in a removal process, the copper plating layer is removed by selective etching, thereby to produce a hydrogen production filter that is used in a reformer a fuel cell so as to be capable of stably producing high purity hydrogen gas.

Abstract: A method for processing a substrate in a plasma processing chamber is provided. The substrate is disposed above a chuck and surrounded by an edge ring. The edge ring is electrically isolated from the chuck. The method includes providing RF power to the chuck. The method also includes providing a tunable capacitance arrangement. The tunable capacitance arrangement is coupled to the edge ring to provide RF coupling to the edge ring, resulting in the edge ring having an edge ring potential. The method further includes generating a plasma within the plasma processing chamber to process the substrate. The substrate is processed while the tunable capacitance arrangement is configured to cause the edge ring potential to be dynamically tunable to a DC potential of the substrate while processing the substrate.

Abstract: Block copolymers can be self-assembled and used in methods as described herein for sub-lithographic patterning, for example. The block copolymers can be diblock copolymers, triblock copolymers, multiblock copolymers, or combinations thereof. Such methods can be useful for making devices that include, for example, sub-lithographic conductive lines.

Abstract: Methods for fabricating sub-lithographic, nanoscale microchannels utilizing an aqueous emulsion of an amphiphilic agent and a water-soluble, hydrogel-forming polymer, and films and devices formed from these methods are provided.

Abstract: The present invention includes a diblock copolymer system that self-assembles at very low molecular weights to form very small features. In one embodiment, one polymer in the block copolymer contains silicon, and the other polymer is a polylactide. In one embodiment, the block copolymer is synthesized by a combination of anionic and ring opening polymerization reactions. In one embodiment, the purpose of this block copolymer is to form nanoporous materials that can be used as etch masks in lithographic patterning.

Abstract: A substrate processing method includes a water removing step of removing water from a substrate, a silylating step of supplying a silylating agent to the substrate after the water removing step, and an etching step of supplying an etching agent to the substrate after the silylating step. The substrate may have a surface on which a nitride film and an oxide film are exposed and in this case, the etching step may be a selective etching step of selectively etching the nitride film by the etching agent. The etching agent may be supplied in a form of a vapor having an etching component.

Abstract: In one embodiment, a pattern forming method includes: forming a functional layer having a functional group to cross-link a first polymer on a substrate; forming a diblock copolymer layer having the first polymer and a second polymer on the functional layer; self-assembling the diblock copolymer layer to form a self-assembled layer, the self-assembled layer having a first domain corresponding to the first polymer, and a plurality of second domains corresponding to the second polymer and surrounded by or interposed in the first domain; cross-linking the first polymer in the self-assembled layer with the functional group in the functional layer to form a bonding layer disposed in the self-assembled layer and bonded to the functional layer; and washing or etching the self-assembled layer to remain the bonding layer.

Abstract: An article includes an electrodeposited metallic material including Co with a minimum content of 75% by weight. The metallic material has a microstructure which is fine-grained with an average grain size between 2 and 5,000 nm and/or an amorphous microstructure. The metallic material forms at least part of an exposed surface of the article. The metallic material has an inherent contact angle for water of less than 90 degrees at room temperature when measured on a smooth exposed surface portion of the metallic material which has a maximum surface roughness Ra of 0.25 microns. The metallic material has an exposed patterned surface portion having surface structures having a height of between at least 5 microns to about 100 microns incorporated therein to increase the contact angle for water at room temperature of the exposed patterned surface portion to over 100 degrees.

Abstract: A method for silicon micromachining techniques based on high aspect ratio reactive ion etching with gas chopping has been developed capable of producing essentially scallop-free, smooth, sidewall surfaces. The method uses precisely controlled, alternated (or chopped) gas flow of the etching and deposition gas precursors to produce a controllable sidewall passivation capable of high anisotropy. The dynamic control of sidewall passivation is achieved by carefully controlling fluorine radical presence with moderator gasses, such as CH4 and controlling the passivation rate and stoichiometry using a CF2 source. In this manner, sidewall polymer deposition thicknesses are very well controlled, reducing sidewall ripples to very small levels. By combining inductively coupled plasmas with controlled fluorocarbon chemistry, good control of vertical structures with very low sidewall roughness may be produced.

Abstract: A method for manufacturing a silicon structure according to the present invention includes, in a so-called dry-etching process wherein gas-switching is employed, the steps of: etching a portion in the silicon region at a highest etching rate under a high-rate etching condition such that the portion does not reach the etch stop layer; subsequently etching under a transition etching condition in which an etching rate is decreased with time from the highest etching rate in the high-rate etching condition; and thereafter, etching the silicon region under a low-rate etching condition of a lowest etching rate in the transition etching condition.

Abstract: A method of suppressing the etch rate for exposed silicon-and-nitrogen-containing material on patterned heterogeneous structures is described and includes a two stage remote plasma etch. The etch selectivity of silicon relative to silicon nitride and other silicon-and-nitrogen-containing material is increased using the method. The first stage of the remote plasma etch reacts plasma effluents with the patterned heterogeneous structures to form protective solid by-product on the silicon-and-nitrogen-containing material. The plasma effluents of the first stage are formed from a remote plasma of a combination of precursors, including nitrogen trifluoride and hydrogen (H2). The second stage of the remote plasma etch also reacts plasma effluents with the patterned heterogeneous structures to selectively remove material which lacks the protective solid by-product. The plasma effluents of the second stage are formed from a remote plasma of a fluorine-containing precursor.

Abstract: A method of etching a sacrificial layer for a micro-machined structure, the sacrificial layer positioned between a layer of a first material and a layer of a second material, the etching being carried out by an etching agent. The method includes: providing at least one species having an affinity for the etching agent greater than that of the layers of first material and second material and less than or equal to that of the sacrificial layer; and then etching the sacrificial layer by the etching agent, the etching being carried out to eliminate at least partially the sacrificial layer and then to eliminate at least partially the species.

Abstract: A method for clearing native oxide is described. A substrate is provided, including an exposed portion whereon a native oxide layer has been formed. A clearing process is performed to the substrate using nitrogen trifluoride (NF3) and ammonia (NH3) as a reactant gas, wherein the volumetric flow rate of NF3 is greater than that of NH3.

Abstract: The present invention relates to a method for treating a block copolymer solution, wherein the method comprises: providing a solution comprising a block copolymer in a non aqueous solvent; and, treating the solution to remove metals using an ion exchange resin. The invention also relates to a method of forming patterns using the treated block copolymer.

Abstract: Embodiments hereof relate to a guidewire formed from an elongated shaft, at least a portion of the shaft having an outer layer, a plurality of channels formed through the outer layer, and an inner core. The outer layer is formed from a material non susceptible to erosion by an erosion agent and the inner core is formed from a radiopaque material susceptible to erosion by the erosion agent. When exposed to the erosion agent, core material adjacent to the channels is removed to form a pattern of integral radiopaque segments or markers with a plurality of voids therebetween. By controlling the location of channels and the rate of erosion of the core material, the pattern of integral radiopaque segments and voids allow for in situ measurement when viewed under fluoroscopy.

Abstract: Methods for creating nano-shaped patterns are described. This approach may be used to directly pattern substrates and/or create imprint lithography molds that may be subsequently used to directly replicate nano-shaped patterns into other substrates in a high throughput process.

Abstract: A method for producing a component, and a component, in particular a micromechanical and/or microfluidic and/or microelectronic component, is provided, the component including at least one patterned material region, and in a first step the patterned material region is produced in that microparticles of a first material are embedded in a matrix of a second material, and in a second step the patterned material region is rendered porous by etching using a dry etching method or a gas-phase etching method.

Abstract: A method of removing a high molecular weight organic-comprising hard mask or BARC from a surface of a porous low k dielectric material, where a change in the dielectric constant of the low k dielectric material is less than about 5% after application of the method. The method comprises exposing the organic-comprising hard mask or BARC to nitric acid vapor which contains at least 68% by mass HNO3.

Abstract: A method of manufacturing a SiC substrate which has a first principal surface and a second principal surface, includes the step of removing, by a vapor phase etching process, at least a portion of a work-affected layer which is formed by mechanical flattening or cutting on the first principal surface of the SiC substrate.

Abstract: The invention provides a system and process of patterning structures on a carbon based surface comprising exposing part of the surface to an ion flux, such that material properties of the exposed surface are modified to provide a hard mask effect on the surface. A further step of etching unexposed parts of the surface forms the structures on the surface. The inventors have discovered that by controlling the ion exposure, alteration of the surface structure at the top surface provides a mask pattern, without substantially removing any material from the exposed surface. The mask allows for subsequent ion etching of unexposed areas of the surface leaving the exposed areas raised relative to the unexposed areas thus manufacturing patterns onto the surface. For example, a Ga+ focussed ion beam exposes a pattern onto a diamond surface which produces such a pattern after its exposure to a plasma etch.

Abstract: The method for forming nano size turfs on a surface of a transparent polymer film used in a solar cell is disclosed, which comprises a first step for attaching a transparent polymer film on a glass, a second step for installing the glass prepared in the first step on an upper side of the electrodes provided in the interior of a chamber and forming either a vacuum environment or an atmospheric environment, and a third step for supplying an electric power to the electrodes under the environment formed in the second step, etching the transparent polymer film attached on the surface of the glass and forming nano size turfs in circular cone shapes.

Abstract: Methods for processing events occurring in a process chamber are provided. In one method, an operation includes carrying gas and receiving an optical signal from the process chamber to an analysis tool that operates in response to the optical signal having a signal-to-noise ratio (SNR) for process analysis. And, dividing the carried gas and optical signal into a plurality of separate gas and optical signals between the process chamber and the analysis tool. The dividing is configured through separate apertures so that the apertures collectively maintain the SNR of the optical signal received at the tool. Methods provide a septum in a second bore dividing the second bore into apertures configured to reduce etching of and deposition on the optical access window and to maintain the desired SNR at the diagnostic end point.

Abstract: The object of the present invention is to provide a masking material for dry etching, which is suitable for fine processing of a magnetic film as thin as a few nm such as NiFe or CoFe constituting a TMR film and capable of simplifying the process for producing a TMR element and reducing production costs related to facilities and materials. This object was solved by a masking material for dry etching of a magnetic material by using a mixed gas of carbon monoxide and a nitrogenous compound as etching gas, which comprises a metal (tantalum, tungsten, zirconium or hafnium) with a melting or boiling point increasing upon conversion thereof into a nitride or carbide.

Abstract: Elemental fluorine and carbonyl fluoride are suitable etchants for producing microelectromechanical devices (“MEMS”). They are preferably applied as mixtures with nitrogen and argon. If applied in Bosch-type process, C4F6 is a highly suitable passivating gas.

Abstract: The present invention relates to a plasma etching method in which a special area for detecting an end point needs not to be set and an equipment therefor. At an etching step of forming SF6 gas into plasma to etch an etching ground on a Si film, the step is configured by two steps of: a large-amount supply step of supplying a large amount of SF6 gas; and a small-amount supply step of supplying a small amount of SF6 gas. An end-point detecting processor 34 measures an emission intensity of Si or SiFx in the plasma at the small-amount supply step, and determines that an etching end point is reached when the measured emission intensity becomes equal to or less than a previously set reference value.

Abstract: A method for etching features of different aspect ratios in a tungsten containing layer is provided. An etch gas is provided containing a tungsten etch component and a deposition component. A plasma is formed from the provided etch gas. A tungsten containing layer patterned with wide and narrow features is etched with the provided plasma.

Abstract: A method for manufacturing a device comprising a structure with nanowires based on a semiconducting material such as Si and another structure with nanowires based on another semiconducting material such as SiGe, and is notably applied to the manufacturing of transistors.

Abstract: A method and system for performing gas cluster ion beam (GCIB) etch processing of various materials is described. In particular, the GCIB etch processing includes setting one or more GCIB properties of a GCIB process condition for the GCIB to achieve one or more target etch process metrics.

Abstract: The invention relates to a method (3) of fabricating a mould (39, 39?, 39?) that includes the following steps: a) providing (10) a substrate (9, 9?) that has a top layer (21, 21?) and a bottom layer (23, 23?) made of electrically conductive, micromachinable material, and secured to each other by an electrically insulating, intermediate layer (22, 22?); b) etching (11, 12, 14, 2, 4) at least one pattern (26, 26?, 27) in the top layer (21, 21?) as far as the intermediate layer (22, 22?) to form at least one cavity (25, 25?) in said mould; c) coating (6, 16) the top part of said substrate with an electrically insulating coating (30, 30?); d) directionally etching (8, 18) said coating and said intermediate layer to limit the presence thereof exclusively at each vertical wall (31, 31?, 33) formed in said top layer. The invention concerns the field of micromechanical parts, in particular, for timepiece movements.

Abstract: A method of multi-stage substrate etching and a terahertz oscillator manufactured by using the method are provided. The method comprises the steps of forming a first mask pattern on any one surface of a first substrate, forming a hole by etching the first substrate using the first mask pattern as an etching mask, bonding, to the first substrate, a second substrate having the same thickness as a depth to be etched, forming a second mask pattern on the second substrate bonded, forming a hole by etching the second substrate using the second mask pattern as an etching mask, and removing an oxide layer having the etching selectivity between the first substrate and the second substrate.

Abstract: An etching method that uses an etch reactant retained within at least a semi-solid media (120, 220, 224, 230). The etch reactant media is applied to selectively etch a surface layer (106, 218, 222). The etch reactant media may be applied to remove metal shorts (222), smearing and eaves resulting from CMP or in failure analysis for uniform removal of a metal layer (218) without damaging the vias, contact, or underlying structures.

Abstract: The present invention uses vacuum deposited thin films of material to create an interface that non-preferentially interacts with different domains of an underlying block copolymer film. The non-preferential interface prevents formation of a wetting layer and influences the orientation of domains in the block copolymer. The purpose of the deposited polymer is to produce nanostructured features in a block copolymer film that can serve as lithographic patterns.

Abstract: The invention provides a dry etching method for processing a wafer having an Ru film formed on a thick Al2O3 film to be used for a magnetic head, capable of realizing high selectivity. In the etching of a wafer having disposed on an NiCr film 15 an Al2O3 film 14, an Ru film 13, an SiO2 film 12 and a resist mask 11, the Ru film 13 is etched via plasma using a processing gas containing Cl2 and O2 (FIG. 1(c)), and thereafter, the Ru film 13 is used as a mask to etch the Al2O3 film 14 via plasma using a gas mixture mainly containing BCl3 and also containing Cl2 and Ar (FIG. 1(d)).

Abstract: A polymer removing apparatus for use in removing polymer annularly adhered to a peripheral portion of a target substrate includes a processing chamber for accommodating the target substrate having the polymer annularly adhered to the peripheral portion thereof; a mounting table for mounting the target substrate thereon; and a laser irradiation unit for irradiating ring-shaped laser light at once to the whole polymer annularly adhered to the target substrate. The polymer removing apparatus further includes an ozone gas supply unit for supplying an ozone gas to the polymer annularly adhered to the target substrate and a gas exhaust unit for exhausting the ozone gas.

Abstract: Radiopaque marker for a catheter includes a collar having a ring shape defining a longitudinal center axis therethrough and at least one helical member extending longitudinally from the collar. A second collar can be provided spaced longitudinally from the first collar. Additionally, a second helical member can extend longitudinally from the collar and be coaxially intertwined with the first helical member in a double helical configuration. The helical member can define a compression spring structure having longitudinal, transverse, and torsional flexibility. A catheter having such a marker and a method of making the marker are also provided.

Abstract: The invention provides a method for subjecting laminated thin films disposed below a photoresist mask pattern to plasma processing, wherein the roughness on the side walls of the formed pattern is reduced, and the LER and LWR are reduced. When etching a material to be processed to form a gate electrode including thin films such as a gate insulating film 205, a conducting layer 204, a mask layer 203 and an antireflection film 202 laminated on a semiconductor substrate 206 and a photoresist mask pattern 201 disposed on the antireflection film, prior to etching the mask pattern 201, plasma is generated from nitrogen gas or a mixed gas including nitrogen gas and deposition gas to subject the mask pattern 201 to a plasma curing process so as to reduce the roughness on the surface and side walls of the mask pattern 201, and then the laminated thin films 202, 203 and 204 disposed below the mask pattern 201 are subjected to a plasma etching process.

Abstract: A method is for processing a substrate. The method includes placing the substrate in a process volume and introducing a process gas or vapour into the process volume and/or subsequently removing gas or vapour from the volume. The step of introducing and/or removing the gas is at least partially performed by moving a movable wall to change the process volume in an appropriate sense.

Abstract: A silicon-containing film on a substrate is subjected to a plasma process using a process gas containing fluorine and carbon, and is thereafter subjected to plasma process using an ammonia gas, whereby ammonium silicofluoride having toxicity and hygroscopic property is adhered to the substrate. The harmful ammonium silicofluoride is removed by the inventive method. After conducting the plasma process using an ammonia gas, the substrate is heated to a temperature not lower than the decomposition temperature of the ammonium silicofluoride to decompose the ammonium silicofluoride in a process container in which the plasma process was conducted, or in a process container connected with the processing vessel which the plasma process was conducted therein and is isolated from a clean room atmosphere.

Abstract: Methods of fabricating the fusible link are directed to processing a multi-layer clad foil having a first layer suitable for forming a fusible link and a second layer suitable for forming one or more welding pads. In some embodiments, the first layer is an aluminum layer and the second layer is a nickel layer. A two-step etching process or a single step etching process is performed on the clad foil to form an etched clad foil having multiple tabs made of the second layer used as current collector conductor pads and battery cell conductor pads, and one or more tabs made of the first layer that form aluminum conductors. The aluminum conductors are shaped and sized to form aluminum fusible conductors during either the etching process or a subsequent stamping process. A single fusible link or an array of fusible links can be formed.

Abstract: The present invention provides a method of forming a nanostructured surface (NSS) on a polymer electrolyte membrane (PEM) of a membrane electrode assembly (MEA) for a fuel cell, in which a nanostructured surface is suitably formed on a polymer electrolyte membrane by plasma treatment during plasma assisted etching in a plasma-assisted chemical vapor deposition (PACVD) chamber, where catalyst particles or a catalyst layer are directly deposited on the surface of the polymer electrolyte membrane having the nanostructured surface.

Abstract: A solvent vapor containing a solvent material capable of dissolving hydrogen fluoride is supplied to a surface of a substrate, thereby covering the surface of the substrate with a liquid film containing solvent material. Thereafter an etching vapor containing a hydrogen fluoride is supplied to the surface of the substrate covered by the liquid film containing the solvent material, thereby etching the surface of the substrate.

Abstract: A micromechanical method for manufacturing a cavity in a substrate, and a micromechanical component manufactured with this method. In this method, in a first step a first layer is produced on or in a substrate. At least one second layer is then applied onto the first layer. An access hole is produced in this second layer. Material of the first layer and of the substrate can be dissolved out through this hole, so that a cavity is produced in the substrate beneath at least a portion of the second layer. This second layer above the cavity can subsequently be used as a membrane. In addition, the possibility also exists of depositing further layers onto the second layer, only the totality of which layers constitutes the membrane. The material of the first layer is selected so that dissolving out the material of the first layer produces a transition edge in the first layer, which edge at is at a predefinable angle between the substrate and the second layer.

Abstract: To remove the deposit including a high dielectric constant film deposited on an inside of a processing chamber, by using a cleaning gas activated only by heat. The method includes the steps of: loading a substrate or a plurality of substrates into the processing chamber; performing processing to deposit the high dielectric constant film on the substrate by supplying processing gas into the processing chamber; unloading the processed substrate from the inside of the processing chamber; and cleaning the inside of the processing chamber by supplying a halide gas and an oxygen based gas into the processing chamber, and removing the deposit including the high dielectric constant film deposited on the inside of the processing chamber, and in the step of cleaning the inside of the processing chamber, the concentration of the oxygen based gas in the halide gas and the oxygen based gas is set to be less than 7%.

Abstract: Methods of dry etching silicon-containing dielectric films are described. The methods include maintaining a relatively high temperature of the dielectric films while etching in order to achieve reduced solid residue on the etched surface. Partially or completely avoiding the accumulation of solid residue increases the etch rate.

Abstract: A substrate processing method is used for a substrate processing system having a substrate processing device and a substrate transfer device. The substrate processing method includes a substrate transfer step of transferring a substrate and a substrate processing step of performing a predetermined process on the substrate. The substrate transfer step and the substrate processing step include a plurality of operations, and at least two operations among the plurality of the operations are performed simultaneously. Preferably, the substrate processing device includes an accommodating chamber, a mounting table placed in the accommodating chamber to be mounted thereon the substrate, and a heat transfer gas supply line for supplying a heat transfer gas to a space between the substrate mounted on the mounting table and the mounting table.

Abstract: In the present invention, provided is a method of forming a mask pattern by which a fine thin film pattern may be formed more easily with higher resolution and precision. In the method of forming a mask pattern, a photoresist pattern having an opening is formed on a substrate, then, an inorganic film is formed so as to cover the upper surface of the photoresist pattern and the inside of the opening, then the inorganic film on the upper surface of the photoresist pattern is removed by a dry etching process. Subsequently, an inorganic mask pattern is formed by removing the photoresist pattern. The inorganic mask pattern thus formed hardly produces an issue of deformation such as physical displacement even when it is heated in the dry etching process.