Abstract: An optical waveguide having a plurality of optical paths is formed on a substrate. A reflection mechanism is arranged above the optical waveguide. The reflection mechanism includes mirror components, each of which has an inclined reflective surface, and a mask having a plurality of openings. Laser is irradiated to the mirror components and optical path conversion inclined surfaces are formed in the plurality of optical paths at the same time by the laser reflected on the mirror components.

Abstract: Provided are an insulating ceramic paste, a ceramic electronic component, and a method for producing the ceramic electronic component that allow prevention of solder shorts between narrow-pitch terminal electrodes and suppression of generation of cracks in an insulator covering a portion of terminal electrodes during a firing step. The ceramic electronic component includes a ceramic multilayer substrate, terminal electrodes formed on a surface of the ceramic multilayer substrate, and an insulating ceramic film formed on the surface of the ceramic multilayer substrate so as to cover a portion of the terminal electrodes. An exposed surface portion (celsian-crystal-rich layer) of the insulating ceramic film has a thermal expansion coefficient that is lower than the thermal expansion coefficient of the ceramic multilayer substrate.

Abstract: Provided herein are apparatuses and methods, including patterning a first set of features in a servo zone to form a patterned servo zone while a first mask protects a data zone from the patterning. The first mask may be removed from the data zone. The apparatuses and methods may further include patterning a second set of features in the data zone to form a patterned data zone while a second mask protects the patterned servo zone from the patterning.

Abstract: A method of forming an optical structure in a continuous manufacturing process includes providing a continuous ribbon of flexible glass substrate (134) having a thickness of no more than 0.3 mm. The continuous ribbon of flexible glass substrate has a first side and a second side separated by a plane formed by the ribbon of flexible glass substrate. A liquid polarizer material (142) is applied on the ribbon of flexible glass substrate at one of the first and second sides as the continuous ribbon of flexible glass substrate moves by a polarizer material application apparatus to form a polarizing layer. A conductive material (150) is applied on the ribbon of flexible glass substrate at one of the first and second sides to form a touch layer for a touch sensitive display.

Abstract: There are disclosed an information-display-equipped electric-heating-type heater, and a method of using the above information. An information-display-equipped electric-heating-type heater includes a tubular honeycomb structure made of a conductive material and having porous partition walls to define and form a plurality of cells which become through channels for a fluid and extend from one end face to the other end face, and a circumferential wall positioned in an outermost circumference; and a pair of electrodes disposed on the circumferential wall of the honeycomb structure, and information concerning a heater performance of the electric-heating-type heater is displayed in the honeycomb structure.

Abstract: A method of making a glass having antimicrobial properties and high compressive stress. The method includes a first ion exchange step in which potassium cations are exchanged for sodium cations in the base glass to provide a surface layer under compressive stress, followed by a second ion exchange in which silver cations are exchanged for potassium and lithium ions in the glass to produce the antimicrobial glass. In some embodiments, the antimicrobial glass has a maximum compressive stress that is at least 80% of the maximum compressive stress obtained by the potassium-for-sodium exchange in the first bath. A base glass and an ion exchanged glass antimicrobial having antimicrobial properties are also provided.

Abstract: A dielectric ceramic layer includes main phase grains and a secondary phase. The main phase grains include a perovskite-type compound. The perovskite-type compound includes Zr, Mn and at least one element selected from the group consisting of Ti, Ca, Sr, and Ba. In the perovskite-type compound, a molar ratio z between Ti/(Zr+Ti) satisfies 0?z?0.2, a molar ratio between Zr/(Zr+Ti) is equal to 1?z, a molar ratio x between Sr/(Ca+Sr+Ba) satisfies 0?x?1.0, a molar ratio y between Ba/(Ca+Sr+Ba) satisfies 0?y?0.3, a molar ratio between Ca/(Ca+Sr+Ba) is equal to 1?x?y, and a molar ratio m between (Ca+Sr+Ba)/(Zr+Ti) satisfies 0.95?m<1.03. The secondary phase contains segregated Mn. In a body including the dielectric ceramic layer and an internal electrode alternately stacked, the secondary phase is located inside of a second region and not located inside of a third region.

Abstract: Disclosed is a plastic substrate, which includes a plastic film, a reflective and/or conductive metal layer, and a resin layer having a conductive material dispersed therein and which is useful as a lower substrate of a transmissive electronic paper display device or a display device.

Abstract: Resin layers and interlayers exhibiting enhanced adhesion to inorganic surfaces, such as glass, are provided. In some cases, the layers and interlayers may comprise at least one adhesion stabilizing agent for improving adhesion to various surfaces, even in the presence of moisture. Such layers and interlayers may be useful, for example, in multiple layer panels, such as, for example, safety glass used in automotive and architectural applications.

Abstract: In various embodiments, a substrate is provided. The substrate may include: a ceramic carrier having a first side and a second side opposite the first side; a first metal layer disposed over the first side of the ceramic carrier; a second metal layer disposed over the second side of the ceramic carrier; and a cooling structure formed into or over the second metal layer.

Abstract: A printed circuit board includes an inner layer having a supporting pattern and via pad patterns that are disposed to be spaced apart from each other in a lateral direction, an outer layer disposed over or below the inner layer and including a circuit pattern, a via plug connecting the circuit pattern layer to any one of the via pad patterns. The supporting pattern is stiffer than the via pad patterns, and at least two of the via pad patterns are electrically connected to each other by a via pad connecting pattern located at substantially the same level as the via pad patterns.

Abstract: A method for forming an oxide coated substrate comprising heating a pre-coating mixture in the presence of a substrate to synthesize an oxide coating on the substrate. The pre-coating mixture comprises a solubilized reducing additive, a solubilized oxidizing additive, and the substrate. The heating is conducted at a temperature sufficiently high enough to exothermically react the solubilized reducing additive and solubilized oxidizing additive and low enough to control the phase and composition of the oxide.

Abstract: A method for producing an optical substrate includes: a step of preparing a long film-shaped mold having a concave-convex pattern surface having a concave-convex pattern; a step of forming a coating film made of a sol-gel material on the concave-convex pattern surface of the film-shaped mold; a step of adhering the coating film, which is formed on the concave-convex pattern surface of the film-shaped mold, to a substrate by arranging the concave-convex pattern surface of the film-shaped mold on which the coating film made of the sol-gel material is formed to face the substrate and by pressing a pressing roll against a surface of the film-shaped mold on a side opposite to the concave-convex pattern surface; a step of releasing the film-shaped mold from the coating film; and a step of curing the coating film adhered to the substrate.

Abstract: A coil component is of the type where a helical coil is directly contacting a magnetic body where such coil component still meets the demand for electrical current amplification. The coil component is structured in such a way that a helical coil is covered with a magnetic body. The magnetic body is mainly constituted by magnetic alloy grains and does not contain glass component, and each of the magnetic alloy grains has an oxide film of the grain on its surface.

Abstract: A light-emitting diode device has a first carrier and at least one light-emitting diode chip, which is arranged on the first carrier. The first carrier has at least one first and one second carrier part, wherein the light-emitting diode chip rests only on the first carrier part. Furthermore, the first and second carrier parts each have a thermal conductivity. The thermal conductivity of the first carrier part is at least 1.5 times the thermal conductivity of the second carrier part. The first carrier part is surrounded laterally by the second carrier part.

Abstract: A decal printing paper for ceramic surfaces has a base paper coated with a water-soluble release layer, an image transfer layer made of liquid cover coat with glass/ceramic flux added, and a printed image layer. The glass/ceramic flux contains glass frit with a relatively low melting point to provide a one-step printing paper with a glass/ceramic flux that delivers the required adhesion, as well as reducing the firing temperature. The image transfer layer can also include a dye colorant to provide a visual indication of a functional characteristic of the decal printing paper.

Abstract: In a semiconductor device 100 according to the present invention in which a semiconductor member 120 is stacked on a substrate 110, the semiconductor member 120 and the substrate 110 are bonded together by means of a semiconductor device bonding material 130 of which main component is zinc. Further, a coating layer to prevent diffusion of the semiconductor device bonding material 130 is provided on at least one of the surface of the substrate 110 and the surface of the semiconductor member 120. In addition, the coating layer 140 is configured such that a barrier layer 141 composed of nitride, carbide, or carbonitride and a protective layer 142 composed of a noble metal are stacked. Further, the nitride, the carbide, or the carbonitride composing the barrier layer 141 is selected so as to have free energy smaller than that of a material composing an insulating layer 111 provided in the substrate 110.

Abstract: A via-holed ceramic substrate can be manufactured in a simple method by providing a via-holed ceramic substrate comprising: a sintered ceramic substrate; an electroconductive via formed in the sintered ceramic substrate, the electroconductive via having an electroconductive metal closely filled in a through-hole, the electroconductive metal containing a metal (A) having a melting point of 600° C. to 1100° C., a metal (B) having a melting point higher than the melting point of the metal (A), and an active metal; and an active layer formed in the interface between the electroconductive via and the sintered ceramic substrate.

Abstract: Disclosed herein are a thin film electrode ceramic substrate and a method for manufacturing the same. The thin film electrode ceramic substrate includes: a ceramic substrate; one or more anti-etching metal layers formed in a surface of the ceramic substrate; thin film electrode pattern formed on the anti-etching metal layers; and a plating layer formed on the thin film electrode pattern, wherein respective edge portions of the thin film electrode pattern are contacted with the anti-etching metal layer, and thus, an undercut defect occurring between the surface of the ceramic substrate and the thin film electrode pattern and between the thin film electrode patterns due to an etchant can be prevented and the binding strength of the entire thin film electrode pattern can be enhanced, resulting in securing durability and reliability of the thin film electrode patterns.

Abstract: There are provided a laminated ceramic electronic component and a method of fabricating the same. The laminated ceramic electronic component include a ceramic body including a dielectric layer; and first and second internal electrodes disposed to face each other, having the dielectric layer interposed therebetween within the ceramic body, wherein the ceramic body includes an active layer that is a capacitance forming part and a cover layer that is a non-capacitance forming part formed on at least one of a top surface and a bottom surface of the active layer, and when a thickness of the ceramic body is t and a thickness of the cover layer is T, T?t×0.05 is satisfied and when an average particle diameter of a dielectric grain in the active layer is Da and an average particle diameter of a dielectric grain in the cover layer is Dc, 0.7?Dc/Da?1.5 is satisfied.

Abstract: A fabrication resource receives a base material such as metal or other suitable material. The fabrication resource applies optical energy to a surface of the base material. Application of the optical energy transforms a texture on the surface of the base material. Subsequent to transforming the texture on the surface of the base material, the fabrication resource then adheres a supplemental material such as paste including glass powder to the transformed texture on the surface. Application of heat to the paste fuses the glass powder of the applied paste into a glass layer that adheres to the transformed texture. The fabrication resource contacts an electronic circuit device onto an exposed facing of the glass layer and reheats the combination of the electronic circuit device, glass layer, and base material. The application of heat secures the electronic circuit device to the layer of glass and corresponding base material.

Abstract: “Green”, ceramic tapes intended as building blocks for making complex, fully ceramic components and devices for electronic-, lab-on-chip-, and sensing applications, the manufacture of which comprises in sequence: I. mixing of a ceramic “green” paste, II. homogenisation of a ceramic “green” paste, III. dimensioning and optionally structuring the ceramic “green” paste, IV. drying of the dimensioned and structured ceramic paste, in which: step iii) is performed in a combination of an extruder and a calender, the extruder being provided with a circular extrusion die, splitting and unfolding the extruded tube to a flat, continuous tape strip, using methylcellulose or derivatives thereof as binder, and, an additional step chosen among cutting and punching the thus dimensioned and optionally structured “green” paste, thereby making thick, “green” tapes. A method for its manufacture is also contemplated.

Abstract: The invention relates to an enamelled part (3, 11, 21) for a dial comprising a ceramic substrate (31) coated with a first enamel layer (4?, 12, 24, 33) to improve the appearance of said part. According to the invention, the part includes at least one other enamel layer (6?, 8?, 9, 14, 16, 25, 35, 37, 39, 41, 43, 45) partially covering the first enamel layer (4?, 12, 24, 33) so as to form a decoration with a similar improved appearance. The invention concerns the field of timepieces, jewellery and gems.

Abstract: A method of printing a decoration on a substrate includes applying an ink coating in a predetermined design on the substrate by inkjet printing. The ink coating is cured to form a cured ink coating, and a portion of the cured ink coating is trimmed. Residual ink particles generated by the trimming are cleaned off the substrate. A printed substrate includes a substrate and a decoration printed on the substrate. The decoration comprises at least one layer of an inkjet-printed ink coating free of a saw edge and having a thickness in a range from 1.5 ?m to 5 ?m.

Abstract: A coated substrate. The coated substrate includes a unitary substrate having a major surface. A first coating is applied to a first surface segment of the major surface. A second coating applied to a second surface segment of the major surface. The first coating is different than the second coating.

Abstract: A layer system having a layer region, whereby the layer region has a single-crystal silicon substrate with a front side and a back side, and whereby a textured surface is formed on the front side and the textured surface has a topography with different heights and a thin film layer of a metal oxide and/or an oxide ceramic is formed on the textured surface, whereby the thin film layer covers the textured surface only partially.

Abstract: Modified low emissivity (low-E) coated glass, so that windows using the processed glass allow uninterrupted use of RF devices within commercial or residential buildings. Glass processed in the manner described herein will not significantly diminish the energy conserving properties of the low-E coated glass. This method and apparatus disrupts the conductivity of the coating in small regions. In an embodiment, the method and apparatus ablates the low-E coating along narrow contiguous paths, such that electrical conductivity can no longer occur across the paths. The paths may take the form of intersecting curves and/or lines, so that the remaining coating consists of electrically isolated areas. The method and apparatus are applicable both to treating glass panels at the factory as well as treating windows in-situ after installation.

Abstract: When a multilayer ceramic substrate with a cavity is reduced in thickness, a bottom wall portion defining the bottom of the cavity is reduced in thickness, thereby leading to the problem that the bottom wall portion is likely to be broken. A bottom wall portion defining a cavity of a multilayer ceramic substrate has a stack structure formed with a high thermal expansion coefficient layer sandwiched between first and second low thermal expansion coefficient layers. This configuration generates compression stress in the low thermal expansion coefficient layers during a cooling process after firing, thereby allowing the mechanical strength at the bottom wall portion to be improved.

Abstract: A glass panel includes a first surface, and a second surface and wherein the first and second surfaces are spaced apart by thickness of the glass panel. A first image is printed on the first surface of the glass panel and a second image is printed on same first surface of the glass panel and at least partially overlapping the first image. The second image printed on the first surface and at least partially overlapping the first image forms at least partially opaque imbedded into the glass panel image that when covered by a fluid becomes transparent to reveal the first image printed on the second surface of the glass panel.

Abstract: The present disclosure is directed to a metal-containing apparatus including a substrate member constructed of a metal that is highly resistant to pitting corrosion and wear in aggressive media. An exemplary metal-containing apparatus is a plate heat exchanger. The metal includes an oxidation layer on the surface thereof and a thin metal oxide nanoporous film on top of the oxidation layer. The nanoporous film is highly compliant and is comprised of oxygen and aluminum, titanium, silicon, zirconium and combinations thereof.

Abstract: Pillar delivery films for vacuum insulated glass units. The delivery films include a support film or pocket tape, a sacrificial material on the support film, and a plurality of pillars. The pillars are at least partially embedded in the sacrificial material or formed within sacrificial material molds, and the sacrificial material is capable of being removed while leaving the pillars substantially intact. In order to make an insulated glass unit, the delivery films are laminated to a receptor such as a glass pane, and the support film and sacrificial material are removed to leave the pillars remaining on the glass.

Abstract: A laminate structure having a first chemically strengthened glass layer, a second chemically strengthened glass layer, and a polymer interlayer structure intermediate the first and second glass layers. The polymer interlayer structure can include a first polymeric layer adjacent to the first glass layer, a second polymeric layer adjacent to the second glass layer, and a polymeric rigid core intermediate the first and second polymeric layers.

Abstract: The invention provides a ceramic green sheet having plasticity, punching property, and sinterability of satisfactory levels as well as a low percent (heat) shrinkage. In the production of a ceramic slurry serving as a raw material of the sheet, ingredients thereof are mixed under such conditions that the functional group ratio (polyol to isocyanate) is 1.5/11.5 to 11.5/11.5; the urethane resin formed from isocyanate and polyol has a repeating-unit-based molecular weight of 290 to 988; and the ratio by weight of the urethane resin to a ceramic powder falls within a range of 4.5 to 10 parts by weight of the urethane resin with respect to 100 parts by weight of the ceramic powder. A ceramic green sheet having, in well balance, all of the properties (i.e., plasticity, punching property, sinterability, and (heat) shrinkage) required for facilitating subsequent processes such as mechanical working and firing can be provided.

Abstract: Prepregs and laminates made from resin compositions having a free resin portion and a resin impregnated reinforcing material portion where the resin includes one or more base resins and one or more high Dk materials wherein the one or more high Dk materials are present in the resin composition in an amount sufficient to impart the resin composition with a cured DkW that matches the DkWR of a resin impregnated reinforcing material to which the resin composition is applied to within plus or minus (±) 15%.

Abstract: A manufacturing method and structure of having a porcelain or glass product formed integrally with a label in a mold includes a male mold, a first female mold and a second female mold. After the first female mold is combined with the male mold, plastics is injected to form a soft mold sleeve on the male mold and then a porcelain or glass product is fitted on the soft mold sleeve. After the second female mold is combined with the male mold, plastics is injected to form a plastic layer on the outer surface of the product and then, a radio frequency identification chip is provided between the product and the plastic layer or a label is positioned in the mold cavity of the second female mold, which is combined with the male mold. Then plastic is injected to form a plastic layer covered on the surface of the product and combined with the label integrally.

Abstract: A radar reflection-damping glazing includes a first substrate and a second substrate arranged above the first substrate in terms of surface area. A first radar-reflecting structure is arranged on the outside surface or on the inside surface of the first substrate. A second radar-reflecting structure is arranged on the inside surface or on the outside surface of the second substrate. The first radar-reflecting structure is an electrically conducting coating, into which linear decoated regions are introduced.

Abstract: The embodiments disclose a block copolymer assembly structure, including a first pattern and second pattern with a first density of patterned features integrated in data and servo zones, a silicon substrate with thin film layers deposited thereon and patterned using the first density of first pattern and second pattern features and a template fabrication pattern with a second density greater than the first density created using ordered block copolymer periodic structures across a portion of the substrate.

Abstract: Techniques for carbon nanotube (CNT) solubilization and surface-selective deposition via polymer-mediated assembly are provided. In one aspect, a method for self-assembly of carbon nanotubes on a substrate is provided. The method includes the following steps. A charge is created on one or more surfaces of the substrate. The substrate is contacted with carbon nanotube-polymer assemblies dispersed in a solvent, wherein the carbon nanotube-polymer assemblies include the carbon nanotubes wrapped in a polymer having side chains with charged functional groups, and wherein by way of the contacting step the carbon nanotube-polymer assemblies selectively bind to the charged surfaces of the substrate based on complementary electrostatic interactions between the charged functional groups on the polymer and the charged surfaces of the substrate and thereby self-assemble on the substrate. A resulting structure is also provided.

Abstract: This disclosure features use of a paper or polymer film that includes a slip agent that can transfer to its surfaces. Once the paper or film is pressed against a glass sheet, this will leave a thin surface roughness of slip agent that can prevent or reduce glass surface scratches from other surfaces or particles during shipping or finishing (e.g., cutting to size, conveyance of glass), thereby improving the yield of glass shipments between glass forming plants and customers. The thin discontinuous layer of slip agent remaining on the glass surface can be washed off easily in subsequent washing processes. The paper or film can have the slip agent imbibed within the paper or coated on it as a surface member.

Abstract: It is an object to provide a member with a sealing material layer having good sealability when low-power sealing laser light is used. A member with a sealing material layer includes a substrate having a sealing region on a surface; and a sealing material layer on the sealing region and containing sealing glass and a low-expansion filler, wherein the sealing material layer has a first region on the substrate side with respect to a center of the layer and a second region opposite the substrate with respect to the center, and has, in a cross section taken along the thickness direction of the sealing material layer, a part where a ratio A/B between a proportion “A” of an area of the low-expansion filler in the first region and a proportion “B” of an area of the low-expansion filler in the second region is less than 1.0.

Abstract: There are provided a method for producing a transfer structure, in which detachment between a transfer-receiving material and a matrix can be easily achieved without destroying the fine pattern, the transfer pattern of the matrix is satisfactorily transferred to the transfer-receiving material, and the durability of the matrix is maintained for a long time during repeated transfer; and a matrix for use in the method. A film of a silane coupling agent represented by the following formula (I) is formed on a surface of a matrix having a transfer pattern formed on the surface thereof, a transfer-receiving material is applied thereon to transfer the pattern on the surface of the matrix, and the transfer-receiving material is detached from the matrix to obtain a transfer structure formed of the transfer-receiving material.

Abstract: To prevent the breakage of the joint between a ceramic substrate and a glass epoxy substrate. The copper column is formed by a wiredrawing step for drawing a copper wire formed linearly to a predetermined diameter; a cutting step for cutting the copper wire, which has been drawn in the wire drawing step, in a predetermined length; a pressing step for pressing one end of the copper wire, which has been cut in the cutting step, in a longitudinal direction to form a copper column member; and an annealing step for annealing the copper column member, which has been formed in the pressing step, by maintaining a heating period of 60 minutes or longer at 600° C. or higher. Thereby, the Vickers hardness of the copper column becomes is 55 HV or less and the copper column is softened.

Abstract: A refrigerated merchandiser including a case defining a product display area and a door coupled to the case to provide access to the product display area. The door includes a glass panel assembly including a glass panel, and a conductive coating applied to the glass panel and defining a serpentine conductive path on the glass panel. The merchandiser also includes a power supply in electrical communication with the conductive coating to heat the glass panel along the serpentine conductive path.

Abstract: Certain example embodiments relate to a method of making a coated article and/or glazing (e.g., for automobile, window, and/or other applications). A colored paint that is not technically a frit is used to form a desired pattern. The paint is screen printed on a substrate. Screen printing parameters are selected, e.g., so that the mesh has a high threads per inch count; the paint is pushed through the screen using hydraulic forces that account for a sheer thinning property of the paint by balancing squeegee speed, squeegee angle relative to the screen, and hardness of the squeegee; and/or relative humidity above and/or near the screen is at least about 80%. Preferably, the paint is substantially fully curable at 400 degrees C. or less. The substrate with the pattern thereon may be heat treated in certain example embodiments and possibly built into an insulated glass unit or other product.

Abstract: The invention relates to a multi-functional label slide, particularly to a label slide adapted to be marked by means of laser induction, thermal induction or ink-jet process. The label slide comprises a substrate wherein at least one area is formed as a mark area. The mark area at least comprises the following structure: a first label layer formed on at least one side of the mark area and a second label layer formed on one side of the first label layer opposite to the substrate. Therefore, the label slide of the invention can be marked by at least two marking ways mentioned above.

Abstract: A method for manufacturing a glass cover is provided, which includes following steps. A glass substrate is provided, wherein the glass substrate has a front surface and a back surface opposite to the front surface, and the front surface has a display region and a non-display region adjacent to the display region. The non-display region of the glass substrate is hazed. A glass cover and an electronic device are also provided. The glass cover is adapted to be disposed at an installation opening of a casing of the electronic device. The glass cover includes a glass substrate. The glass substrate has a front surface and a back surface opposite to the front surface, and the front surface has a display region and a non-display region adjacent to the display region, and the non-display region is hazed.

Abstract: Provided are a strengthened glass panel for protecting a surface of a display device and a method for manufacturing the same. Here, the strengthened glass panel includes a strengthened glass layer, a laminate layer uniformly formed on the bottom surface of the strengthened glass layer, and a separation layer configured to cover the laminate layer, wherein the laminate layer is formed by transferring a transfer film. Accordingly, the strengthened glass panel for protecting a surface of a display device can have improved characteristics of neatly attaching the laminate layer to the surface of the display device without lifting or occurrence of air bubbles and easily detaching the laminate layer when a uniform laminate layer is formed on strengthened glass by means of a transfer film.

Abstract: A method and apparatus for injection molding plastic parts is described. In one embodiment, at least two materials are simultaneously injected into a mold. The resulting molded part can include at least two different regions. Each region can have distinct physical properties. Positions of the regions within the molded part can be at least partially controlled by controlling flow fronts of the at least two materials within the mold.

Abstract: The invention comprises a method of forming a concrete structure. The method comprises placing plastic concrete in a form of a desired shape, encasing the concrete in insulating material having insulating properties equivalent to at least 1 inch of expanded polystyrene and allowing the plastic concrete to at least partially cure inside the insulating material. An insulated concrete form and a method of using the insulated concrete form are also disclosed.

Abstract: Fabrication of thin sheets of glass or other substrate material for use in devices such as touch sensor panels is disclosed. A pair of thick glass sheets, typically with thicknesses of 0.5 mm or greater each, may each be patterned with thin film on a surface, sealed together to form a sandwich with the patterned surfaces facing each other and spaced apart by removable spacers, either or both thinned on their outside surfaces to thicknesses of less than 0.5 mm each, and separated into two thin glass sheets. A single thick glass sheet, typically with a thickness of 0.5 mm or greater, may be patterned, covered with a protective layer over the pattern, thinned on its outside surface to a thickness of less than 0.5 mm, and the protective layer removed. This thinness of less than 0.5 mm may be accomplished using standard LCD equipment, despite the equipment having a sheet minimum thickness requirement of 0.5 mm.