Components of an electronic device, such as glass components, are susceptible to surface damage. Glass components can be strengthened by providing ceramic particles at the exposed surface of the glass. Ceramic particles can also provide optical features, such as color, opacity, and haze to enhance the appearance of the resulting composite article. Where ceramic particles are provided at the exposed surface, the ceramic particles can also produce a desired tactile feature. These features can be provided in various combinations and in different ways across different regions to produce a desired look and feel of the resulting composite article.

A surface-treated infrared absorbing fine particle dispersion liquid wherein surface-treated infrared absorbing fine particles are dispersed in a liquid medium, and are an infrared absorbing transparent substrate having a coating layer in which the surface-treated infrared absorbing fine particles. This is a surface-treated infrared absorbing fine particle dispersion liquid in which surface treated infrared absorbing fine particles are dispersed in a liquid medium, wherein the surface-treated infrared absorbing fine particles are infrared absorbing fine particles, each surface is coated with a coating layer containing at least one selected from a hydrolysis product of a metal chelate compound, a polymer of the hydrolysis product of the metal chelate compound, a hydrolysis product of a metal cyclic oligomer compound, and a polymer of the hydrolysis product of the metal cyclic oligomer compound, and this is an infrared absorbing transparent substrate prepared using the surface-treated infrared absorbing fine particle dispersion liquid.

Glass or glass ceramic substrates are provided that have a decorative coating. Methods for coating a glass or glass ceramic substrate with a decorative coating are also provided. In the method, a first, textured layer is applied which is filled with a further layer, so that a layer material of graded composition is formed.

Disclosed is a glass window having a luminous capability, which is suitable for use in automotive applications, architectural applications, or other applications. Exemplary embodiments of a glass window having a luminous capability include one or more glass sheet layers, a thin film layer having fine particles dispersed in a matrix of a thin film material, and at least one light source for introducing light into the thin film layer. The fine particles scatter the light and generate luminousness of the glass window. Exemplary embodiments of a glass window having luminous capability may further include one or more resinous sheet layers or one or more interlayers such as a plastic film layer.

Glass or glass ceramic substrates are provided that have a decorative coating. Methods for coating a glass or glass ceramic substrate with a decorative coating are also provided. In the method, a first, textured layer is applied which is filled with a further layer, so that a layer material of graded composition is formed.

Methods for manufacturing and/or reinforcing a carbon-containing glass material are disclosed. The method includes supplying a non-thermal equilibrium plasma including a plurality of positive charged gas particles and a plurality of ionized inert gas particles into a reaction chamber, and accelerating at least the plurality of positive charged gas particles through the reaction chamber based on application of an external electric potential to the non-thermal equilibrium plasma. The method includes bombarding a surface-to-air interface of the glass material with the accelerated positive charged gas particles and the ionized inert gas particles, and forming an interphase region in the glass material in response to the bombardment. The method includes forming a compressive stress layer in the glass material in response to the bombardment by at least the ionized inert gas particles. The compressive stress layer may be disposed between the interphase region and the surface-to-air interface of the carbon-containing glass material.

A transparent component of an electronic device having a nano-crystalline layer is disclosed. The nano-crystalline layer may be formed as a series of layers separated by or interspersed with one or more other layers including a non-crystalline or amorphous material. The series of layers may also be interspersed with one or more anti-reflective layers configured to reduce optical reflections off the transparent component. The nano-crystalline layer may be formed by a deposition process or by an ion-implanting and annealing process to form crystals having a size of less than 10 nanometers. The protective coatings may be utilized on portions of an electronic device, such as a housing or a cover glass, to protect the electronic device from scratching and/or damage caused by impact.

A fire-resistant pane including at least one float glass pane with a tin bath side, at least one protective layer that is arranged on the tin bath side in a planar manner, and at least one fire-resistant layer that is arranged on the protective layer in a planar manner, wherein the protective layer contains metal oxide, metal nitride, metal silicide, and/or mixtures or layered compounds thereof.

Provided is a laminate for a light emitting device. The laminate for a light emitting device includes a glass substrate having potassium or a glass substrate coated with a mineral layer containing potassium, and an internal light extraction layer formed from a glass frit on the glass substrate. The internal light extraction layer includes an interface void layer at an interface with the glass substrate or the mineral layer. The laminate has an interface void layer inducing the scattering of light for effectively extracting light, which is lost at the interface between the substrate and the internal light extraction layer, to the outside. The laminate is suitable for the fields of optical devices such as organic light emitting diodes (OLEDs), backlights, lighting industry, etc.

The present invention is a composite film manufacturing method in which a sputtering device is used and a gas of a substance with which can be prepared a mixed gas of a target of a solid substance in a standard state (a temperature of 25? C. and pressure of 100 KPa) (A) and a sputtering gas (B) is used. The method includes: (1) a step for attaching the target (A) to a target installation jig of the sputtering device; (2) a step for reducing the pressure inside a sputtering chamber of the sputtering device to a prescribed first pressure; (3) a step for introducing the mixed gas of the sputtering gas and the gas (B) into the sputtering chamber of the sputtering device such that the inside of the sputtering chamber reaches a second prescribed pressure (greater than or equal to the first prescribed pressure); and (4) a step for applying electric power to the target (A) and using sputtering to form a composite film on the surface of a base material. The sputtering device may be a roll-to-roll scheme sputtering device.