Disclosed herein are methods for making a thin film device and/or for reducing warp in a thin film device, the methods comprising applying at least one metal film to a convex surface of a glass substrate, wherein the glass substrate is substantially dome-shaped. Other methods disclosed include methods of determining the concavity of a glass sheet. The method includes determining the orientation of the concavity and measuring a magnitude of the edge lift of the sheet when the sheet is supported by a flat surface and acted upon by gravity. Thin film devices made according to these methods and display devices comprising such thin film devices are also disclosed herein.

A glass substrate for a high-frequency device, which contains SiO.sub.2 as a main component, the glass substrate having a total content of alkali metal oxides in the range of 0.001-5% in terms of mole percent on the basis of oxides, the alkali metal oxides having a molar ratio represented by Na.sub.2O/(Na.sub.2O+K.sub.2O) in the range of 0.01-0.99, and the glass substrate having a total content of alkaline earth metal oxides in the range of 0.1-13% in terms of mole percent on the basis of oxides, wherein at least one main surface of the glass substrate has a surface roughness of 1.5 nm or less in terms of arithmetic average roughness Ra, and the glass substrate has a dielectric dissipation factor at 35 GHz of 0.007 or less.

An electronic device may include electrical components and other components mounted within a housing. The device may have a display on a front face of the device and may have a glass layer that forms part of the housing on a rear face of the device. The glass layer and other glass structures in the electronic device may be provided with coatings. An interior coating on a glass layer may include multiple layers of material such as an adhesion promotion layer, thin-film layers of materials such as silicon, niobium oxide and other metal oxides, and metals to help adjust the appearance of the coating. A metal layer may be formed on top of the coating to serve as an environmental protection layer and opacity enhancement layer. In some configurations, the coating may include four layers.

A glazing includes a first glass sheet, a resistive coating extending across a part of the first glass sheet, first and second busbars connected to the resistive coating, a data transmission window in the resistive coating, comprising a plurality of deletion lines in the resistive coating, a plurality of channels, formed by the plurality of deletion lines, and at least one conductive element positioned in at least one of the channels. The conductive element is separated from the first and second busbars by the resistive coating.

Embodiments disclosed herein include electronic packages and methods of forming such packages. In an embodiment, an electronic package comprises a core, where the core comprises glass. In an embodiment, a via opening is formed through the core. In an embodiment, the via opening has an aspect ratio (depth:width) that is approximately 5:1 or greater. In an embodiment, the electronic package further comprises a via in the via opening, where the via opening is fully filled.

Provided is a metal film forming method which can form a metal film having excellent adhesion industrially advantageously and a metal film formed by using the method. A method of forming a metal film on a base includes an atomization step of atomizing a raw-material solution into a mist, in which the raw-material is prepared by dissolving or dispersing a metal in an organic solvent containing an oxidant, a chelating agent, or a protonic acid; a carrier-gas supply step of supplying a carrier gas to the mist; a mist supply step of supplying the mist onto the base using the carrier gas; and a metal-film formation step of forming the metal film on part or all of a surface of the base to causing the mist to thermally react.

A composition for forming a conductive film includes at least one of a metal salt (A1) and a metal particle (A2) as component (A) that serves as a metal source of the conductive film, and a metalloxane compound (B). The metal salt (A1) and the metal particle (A2) contain one or more metals selected from the group consisting of Ni, Pd, Pt, Cu, Ag, and Au. The metalloxane compound (B) has at least one metal atom selected from the group consisting of Ti, Zr, Sn, Si, and Al in its main chain. Preferably, the metal salt (A1) is a carboxylate containing a metal selected from the group consisting of Cu, Ag, and Ni. Preferably, the metal particle (A2) has an average particle diameter of 5 nm to 100 nm and comprises a metal selected from the group consisting of Cu, Ag, and Ni.

Method and apparatus for producing metal-coated optical fiber involves feeding a length of glass fiber through a first solution bath so as to plate a first predetermined metal on the glass fiber via electroless deposition. The length of glass fiber is passed continuously from the first solution bath to a second solution bath adapted to plate thereon a second predetermined metal via electrolytic plating such that the optical fiber contacts an electrode only after at least some of the second predetermined metal has been applied. The length of glass fiber may be passed continuously from the second solution bath to a third solution bath adapted to plate thereon a third predetermined metal via electrolytic plating.

Certain example embodiments relate to techniques for improving the uniformity of, and/or conformance to a desired pattern for, metal island layers (MILs) formed on a substrate (e.g., a glass or other substrate), and/or associated products. Certain example embodiments form MILs using a laser or other energy source or magnetic field assisted technique, e.g., to compensate for non-uniformities that otherwise likely would result in the MIL diverging from its desired configuration. For example, a laser or other energy source may introduce heat onto a substrate, enable pulsed laser deposition, raster a target including the MIL metal to be deposited, raster a substrate where the MIL is to be formed, etc. These and/or other techniques may be used to enable the MIL to be formed on the substrate in a desired pattern, e.g., by compensating for implicit non-uniformities of the substrate and/or by selectively creating non-uniformities in how the MIL is formed.

The present invention includes a method for creating a system-in-package in or on photodefinable glass including: providing a photodefinable glass substrate; masking a design layout comprising one or more structures to form one or more integrated lumped element devices as the system-in-package on or in a photodefinable glass substrate; transforming at least a portion of the photodefinable glass substrate to form a glass-crystalline substrate; etching the glass-crystalline substrate to form one or more channels in the glass-crystalline substrate; depositing, growing, or selectively etching a seed layer on a surface of the glass-crystalline substrate to enable electroplating of copper; and electroplating the copper to fill the one or more channels and to deposit copper on the surface of the photodefinable glass to form the one or more integrated lumped element devices.