The invention concerns reflective opaque panels that can be used as facing panels or decorative panels. They consist of a substrate coated with a stack of layers comprising, in the following order, at least (i) a transparent substrate (S), (ii) a first dielectric layer which is a high refractive index dielectric layer (H1), (iii) a second dielectric layer which is a low refractive index dielectric layer (L1), and (vi) a single chromium-based layer.

A projection arrangement for a head-up display, including a composite pane, including an outer pane and an inner pane, which are joined to one another via a thermoplastic intermediate layer, having an upper edge and a lower edge and an HUD region; an electrically conductive coating on the surface of the outer pane or the inner pane facing the intermediate layer or provided within the intermediate layer; and a projector that is aimed at the HUD region; wherein the light of the projector has at least one p-polarised portion and wherein the electrically conductive coating has, in the spectral range from 400 nm to 650 nm, only a single local reflection maximum for p-polarised light, with this maximum in the range from 510 nm to 550 nm.

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.

A method of fabricating a metal thin film-on-glass structure. A glass substrate, on a top surface of which a layer is formed, is prepared. A local area of the glass substrate is etched from a bottom of the glass substrate to expose the layer downwardly, thereby forming an exposed area of the layer. The layer is a metal thin film. The etching includes first-etching the glass substrate to a depth less than a thickness of the glass substrate using a first etching solution containing hydrofluoric acid and at least one of nitric acid and sulfuric acid, resulting in a first-etched portion of the glass substrate; and second-etching the first-etched portion of the glass substrate using an etching solution containing hydrofluoric acid without nitric acid or sulfuric acid, so that the layer is exposed downwardly, whereby the metal thin film is supported by a remaining portion of the glass substrate.

The object is to provide a mask blank substrate, a mask blank, and a transfer mask which can achieve easy correction of a wavefront by a wavefront correction function of an exposure apparatus. The further object is to provide methods for manufacturing them.

A virtual surface shape, which is an optically effective flat reference surface shape defined by a Zernike polynomial, is determined, wherein the Zernike polynomial is composed of only terms in which the order of variables related to a radius is second or lower order and includes one or more terms in which the order of the variables related to a radius is second-order; and the mask blank substrate, in which difference data (PV value) between the maximum value and the minimum value of difference shape between a virtual surface shape and a composite surface shape obtained by composing respective surface shapes of two main surfaces is 25 nm or less, is selected.

A method of fabricating a metal thin film-on-glass structure. A glass substrate, on a top surface of which a layer is formed, is prepared. A local area of the glass substrate is etched from a bottom of the glass substrate to expose the layer downwardly, thereby forming an exposed area of the layer. The layer is a metal thin film. The etching includes first-etching the glass substrate to a depth less than a thickness of the glass substrate using a first etching solution containing hydrofluoric acid and at least one of nitric acid and sulfuric acid, resulting in a first-etched portion of the glass substrate; and second-etching the first-etched portion of the glass substrate using an etching solution containing hydrofluoric acid without nitric acid or sulfuric acid, so that the layer is exposed downwardly, whereby the metal thin film is supported by a remaining portion of the glass substrate.

A quartz etching method of the invention includes forming a mask on a quartz glass substrate and carrying out etching using a hydrofluoric acid-based etchant solution. The quartz etching method includes: preparing a quartz glass substrate; forming a mask having a predetermined pattern on the quartz glass substrate; and carrying out etching on the quartz glass substrate. When the quartz glass substrate is prepared, the quartz glass substrate is selected in accordance with a standard such that a concentration of hydroxyl groups included therein is less than or equal to 300 ppm.

A conductive laminate includes a first organic film, a fine metal wire arranged on the first organic film, and a second organic film arranged to cover the fine metal wire, in which the fine metal wire includes a blackening layer, an intimate attachment layer, and a metal conductive layer in order from a side of the first organic film, and moisture contents of the first organic film and the second organic film are less than 3.00%.

A vehicular variable reflectance mirror reflective element includes a rear glass substrate joined with a front glass sheet via a perimeter seal. An electrochromic medium disposed in an interpane cavity established between the rear glass substrate and the front glass sheet and bounded by the perimeter seal. With the rear glass substrate joined with the front glass sheet, the front glass sheet is cut at a front glass substrate portion to form a front glass substrate. A back plate is attached at the rear of the rear glass substrate. With the front glass sheet cut at the front glass substrate portions to form the front glass substrate having the rear glass substrate joined therewith via the perimeter seal, and with the back plate fixtured at a finishing tool, the cut edges of the front glass substrate are processed to provide a finished perimeter edge of the front glass substrate.

A vehicular variable reflectance mirror reflective element includes a rear glass substrate joined with a front glass sheet via a perimeter seal. An electrochromic medium disposed in an interpane cavity established between the rear glass substrate and the front glass sheet and bounded by the perimeter seal. With the rear glass substrate joined with the front glass sheet, the front glass sheet is cut at a front glass substrate portion to form a front glass substrate. A back plate is attached at the rear of the rear glass substrate. With the front glass sheet cut at the front glass substrate portions to form the front glass substrate having the rear glass substrate joined therewith via the perimeter seal, and with the back plate fixtured at a finishing tool, the cut edges of the front glass substrate are processed to provide a finished perimeter edge of the front glass substrate.