Vanadium oxide nanomaterials dispersed in a polymeric matrix, substrates including the vanadium oxide nanomaterials dispersed in a polymeric matrix, and related methods of making vanadium oxide nanomaterials dispersed in a polymeric matrix are described.

When a laser beam is used to perform shape processing on an edge surface of a disk-shaped glass plate, in order to suppress strain (retardation values) in the main surface of the glass plate, the disk-shaped glass plate is floated above a base, and the edge surface of the glass plate is processed into a target shape by irradiating the edge surface with the laser beam while contactlessly heating the glass plate in a state where the glass plate is floated, and moving the laser beam relative to the edge surface in the circumferential direction of the disk-shaped glass plate.

As described herein, a polyimide chemical composition may be used for coating glass articles. According to embodiments, a coated glass article may include a glass container which may include a first surface and a second surface opposite the first surface, and a low-friction coating bonded to at least a portion of the first surface of the glass container. The low-friction coating may include a polyimide chemical composition. The polyimide chemical composition may be halogenated and the polyimide chemical composition may include a siloxane moiety.

A process for the printing of enamel on a constituent glass sheet of a laminated glazing which can be used in the motor vehicle field and including a stack of thin functional layers sensitive to scratchability. The process makes it possible to deposit an enamel layer on a glass sheet coated with a stack of thin layers.

An electronic device may have a display and a rear housing. A coating may be formed on an inner surface of a display cover layer for the display or on an inner surface of the rear housing. The coating may include one or more inorganic layers such as inorganic layers in a thin-film interference filter or other layer of material. A buffer layer having a polymer with adhesion promotion additive and embedded silicon oxide particles may be interposed between the coating and a glass layer forming the rear housing or between a patterned indium tin oxide coating on a display cover layer and an adhesive layer that attaches a pixel array to the display cover layer.

A method for manufacturing a glass article includes a heating step that heats a heating object made of glass. The heating step includes heating the heating object by converting, by a converter arranged between the heating object and a radiant heat source that radiates infrared light, a spectrum of the infrared light radiated from the radiant heat source and causing the heating object to absorb the infrared light radiated from the converter. The converter includes: an infrared light absorber that generates heat by absorbing the infrared light radiated from the radiant heat source; and an infrared light radiator made of a silicon-containing material. The infrared light radiator is heated through thermal conduction from the infrared light absorber. At least part of a surface of the converter facing the heating object includes at least part of a surface of the infrared light radiator.

A method for coating a glass article includes obtaining a glass article; selecting a coating including a fluorinated polyimide, and coating the glass article with the selected coating including the fluorinated polyimide. The fluorinated polyimide having a cohesive energy density less than or equal to 300 KJ/mol, and a glass transition temperature (T.sub.g) less than or equal to 625 K.

A single and multi-layer flat glass-sensor structure and method of making the flat glass-sensor structure. The flat glass sensor structure comprises at least one flat glass layer, a sensor and a heater. The flat glass layer has a plurality of cutouts that are configured to “suspend” the sensor on top of or in plane with the flat glass layer. The sensor is an electrochemical wafer with at least one sensory element and flat glass connectors. Each flat glass connector is in minimal contact with at least one sensory sub-area. The heater is a resistive heating element that is on top of or in plane with the flat glass layer configured to heat the sensor. The flat glass connectors are configured to provide support for electrical leads to the heater and membrane. The flat glass connectors are also configured to provide temperature insulation of the suspended sensor.

A light glazing for a motor vehicle includes a first transparent sheet, a masking zone with a first unmasked zone, a first light source, coupled optically to a transparent element, called light guide, a first extraction device for extracting light guided in the light guide, the first light extraction device being opposite the first unmasked zone so that one or more of the illuminated patterns are visible on the side of the second main face, on the second main face side, an opaque rear masking element, covering the first light extraction device, the first light extraction device being between the second main face and the rear masking element.

The invention relates to a process for preparing a dichromatic material, in the form of a translucent film, comprising monodisperse nanoparticles formed of gold and optionally of a noble metal chosen from platinum, palladium, silver and copper, and at least one organic macromolecule chosen from proteins, polysaccharides and synthetic polymers; said dichromatic material; and the uses thereof.