The present disclosure relates generally to methods for the integration of electrochromic films onto a substrate, such as a glass window, and the systems/structures formed via such methods.

A projection arrangement for a head-up display (HUD), includes a composite pane, including an outer and an inner pane connected to one another via a thermoplastic intermediate layer, with an HUD region; an electrically conductive coating on the surface of the outer pane or of the inner pane facing or within the intermediate layer; and a projector directed toward the HUD region. The radiation of the projector is p-polarised. The composite pane has reflectance of at least 10% relative to p-polarised radiation in the spectral range from 450 nm to 650 nm. The electrically conductive coating includes at least four electrically conductive layers, which are each arranged between two dielectric layers or layer sequences. The sum of the thicknesses of all electrically conductive layers is at most 30 nm and at least one of the electrically conductive layers has a thickness of at most 5 nm.

An article including a glass or glass ceramic substrate, a noble metal layer, an adhesion promoting layer positioned between and bonded to the substrate and the noble metal layer, and a conductive metal layer positioned on and bonded to the noble metal layer. The adhesion promoting layer includes a siloxy group bonded with the substrate and a thiol group bonded to the noble metal layer. A method for manufacturing an article including applying an adhesion promoting layer comprising mercaptosilane to at least a portion of a glass or glass ceramic substrate, wherein siloxane bonds are formed between the mercaptosilane and the substrate, applying a noble metal layer to the adhesion promoting layer, the noble metal layer bonds with a thiol present in the mercaptosilane, thermally treating the noble metal layer, and applying a conductive metal layer to the noble metal layer.

A method for bonding a conductive metal to an oxide substrate includes applying a porous coating to a surface of the oxide substrate, the porous coating including a porous oxide and catalyst nanoparticles dispersed therein, and depositing a conductive metal onto the porous coating. A portion of the conductive metal may be deposited within the pores of the porous coating to couple the conductive metal to the porous coating. Articles are also disclosed that include the oxide substrate, the porous coating coupled to a surface of the oxide substrate, and the conductive metal coupled to the porous coating. The porous coating may include a porous oxide and catalyst nanoparticles dispersed within the metal oxide. A portion of the conductive metal may be deposited within the pores of the porous coating to interlock the conductive metal to the porous coating.

A laminated vehicle glazing is disclosed, the glazing comprising a first glass ply coated with an electrically conductive coating, a second glass ply, an interlayer ply comprising polyvinyl butyral, and a first busbar comprising a conductive foil, wherein the electrically conductive coating comprises a pyrolytically deposited transparent conductive oxide layer and in that the first busbar is in direct contact with both the electrically conductive coating and the interlayer ply. Preferably the pyrolytically deposited transparent oxide layer comprises doped tin oxide and is the outermost layer of the electrically conductive coating. Also disclosed are a vehicle windshield and a train having a power supply at 25 V to 250 V, comprising a laminated vehicle glazing. A method for manufacturing a laminated vehicle glazing is also disclosed.

A glazing includes a first substrate and a heatable coating formed on the first substrate, and the heatable coating includes at least one heatable layer and at least one deletion substantially enclosing a non-deleted portion of the heatable coating for increasing resistance against current flowing through the heatable coating.

The present invention relates to a glass substrate provided with a stack of thin coating layers formed by a first layer of anti-reflective dielectric material, with a refractive index of 1.65 to 2.65, located above the glass substrate. At least one structure of two layers formed by a first layer of an anti-reflective transparent dielectric material with a refractive index of 1.32 to 1.55, located in the bottom position, and a second layer of a metal functional layer with reflective properties in the infrared range, located in the top position, said structure being located above the first layer of anti-reflective dielectric material. A second layer of absorbent material forming an anti-corrosion barrier for protecting the metal functional layer against oxidation and corrosion. A third layer of an anti-reflective material, said layer being selected from a metal oxide with a refractive index of 1.32 to 1.55, a metal oxide with a refractive index of 1.65 to 1.95 or an aluminum-doped zinc oxide (AZO); and a fourth protective layer made of an anti-reflective material, for increasing the transmission of visible light and the scratch resistance of the substrate, having high transmission of visible light (60%), a solar transmission of less than 60%, a resistance of less than 10 per square and an emissivity of less than 0.10.

The present disclosure relates generally to methods for the integration of electrochromic films onto a substrate, such as a glass window, and the systems/structures formed via such methods.

There are provided an oxide sintered material containing an In.sub.2O.sub.3 crystal phase, a Zn.sub.4In.sub.2O.sub.7 crystal phase and a ZnWO.sub.4 crystal phase, and a method of producing the oxide sintered material. The method includes forming the oxide sintered material by sintering a molded body containing In, W and Zn, and forming the oxide sintered material including placing the molded body at a first constant temperature selected from a temperature range of 500? C. or more and 1000? C. or less for 30 minutes or longer.

A color conversion element includes: a phosphor layer that includes at least one type of phosphor; a reflecting layer stacked on the phosphor layer; a substrate disposed in a position opposite to the reflecting layer; a joining portion interposed between the reflecting layer and the substrate for joining the reflecting layer and the substrate; and an absorbing portion disposed above a principal surface of the substrate closer to the joining portion. The absorbing portion is covered with the joining portion and absorbs laser light having a wavelength that excites the phosphor.