Process for forming a multi-layer electrochromic structure, the process comprising depositing a film of a liquid mixture onto a surface of a substrate, and treating the deposited film to form an anodic electrochromic layer, the liquid mixture comprising a continuous phase and a dispersed phase, the dispersed phase comprising metal oxide particles, metal alkoxide particles, metal alkoxide oligomers, gels or particles, or a combination thereof having a number average size of at least 5 nm.

The present invention relates to transparent glass having a pattern and, more specifically, to transparent glass having a pattern, and having the purpose of allowing a dotted, linear or wave-shaped uneven surface to be formed on the surface of glass at low cost and improving fingerprint resistance, contamination resistance, water repellency and light transmittance by forming a fingerprint-resistant coating layer thereon, such that an uneven surface (100), which has a pattern groove (102) of any one of a plurality of dots, a plurality of linear forms, and a plurality of wave forms, is formed on the surface of a glass substrate by a deposition process or an etching process, a primer layer (40) and a fingerprint-resistant coating layer (50) are formed on the uneven layer, and the width or area of the pattern groove and the spacing distance between the pattern grooves are constant, thereby allowing the uneven surface to be systematically arranged.

The invention relates to a glass substrate for chemical strengthening where a surface is coated by magnetron sputtering with a temporary thin film that reduces the extent of ion exchange upon chemical strengthening and where the temporary thin film can be removed after the chemical strengthening by treatment with an etchant solution. Other embodiments relate to a method for making a chemically strengthened glass substrate with controlled curvature comprising: providing a substrate with opposed surfaces that are durable to a given etchant solution, forming a temporary thin film upon at least part of a surface of the glass substrate, chemically strengthening the glass substrate bearing the temporary thin film, and removing the temporary thin film after said chemical strengthening with said etchant solution. The thickness of the temporary thin film is chosen such that a controlled curvature is obtained upon chemical strengthening.

Disclosed is a glazing unit including an insulating glazing unit that is assembled with at least three panes for use in a window or as a part of a wall in a property, including a first pane that is located closer to the exterior of the property, a second pane located closer to the interior of the property, and a third pane located between the first and the second panes, whereby the first pane is provided on its surface that is facing inwards with a coating that reduces the radiation of heat in the form of an oxide layer burned into the surface of the pane, whereby also the second pane and the third pane are provided with a coating that reduces the radiation of heat in the form of an oxide layer that is burned into the surface of the pane.

Certain example embodiments of this invention relate to articles including anticondensation and/or low-E coatings that are exposed to an external environment, and/or methods of making the same. In certain example embodiments, the anticondensation and/or low-E coatings may be survivable in an outside environment. The coatings also may have a sufficiently low sheet resistance and hemispherical emissivity such that the glass surface is more likely to retain heat from the interior area, thereby reducing (and sometimes completely eliminating) the presence condensation thereon. The articles of certain example embodiments may be, for example, skylights, vehicle windows or windshields, IG units, VIG units, refrigerator/freezer doors, and/or the like.

Disclosed is an inorganic polarizing plate that exhibits improved heat resistance while suppressing an increase in lead time resulting from addition of process steps and an increase in costs. An inorganic polarizing plate 1 includes: a substrate (11) transparent to light having a wavelength within a used band; a plurality of linear reflective film layers (12) arranged on the substrate (11) at pitches smaller than the wavelength of the light within the used band; a plurality of dielectric film layers (13) arranged on the corresponding reflective film layers (12); and a plurality of absorptive film layers (14) arranged on the corresponding dielectric film layers (13). Each of the absorptive film layers (14) includes: a property-oriented layer (15); and a heat-resistance-oriented layer (16) made of the same material as the property-oriented layer (15) and having an extinction coefficient greater than an extinction coefficient of the property-oriented layer (15).

A transparent layered film is produced by forming an anti-water-mark layer on a first side of a transparent resin layer and forming an uneven structure on a surface of the anti-water-mark layer, wherein the anti-water-mark layer comprises a cured product of a curable composition containing a curable resin, a thermoplastic resin, and a metal oxide particle having an average primary particle size of 1 to 100 nm, and the uneven structure has a roughness average Ra of not less than 0.005 and less than 0.03 m, a mean spacing of profile irregularities Sm of 50 to 300 m, an average absolute slope a of less than 0.1, and a ten-point average roughness Rz of less than 0.2 m. Lamination of the film on a glass-containing upper electrode of a touch screen display prevents scattering of glass fragments produced by breakage of the upper electrode, occurrence of water marks, and sparkling on a high-definition display provided with the film.

Certain example embodiments relate to coated articles supporting high-entropy nitride and/or oxide thing film inclusive coatings, and/or methods of making the same. The example high-entropy alloys systems described herein are heat stable and may be used in optical coatings. A first material system that may be used in connection with certain example embodiments includes SiAlN with one or more (and preferably two or more) of elements such as Hf, Y, Zr, Ti, Ta, and Nb. A second material system that may be used in connection with certain example embodiments includes TiO, with one or more (and preferably two or more) of elements such as Fe, Co, Ni, Sn, Zn, and N. The material systems may in some cases be high-index materials that can serve as a substitute for titanium oxide in layer stacks, in some example applications.

Embodiments are directed to systems and methods for material processing in a low gravity environment, and an optical fiber formed in a low gravity environment. In at least one embodiment, a glass part (e.g., a preform, optical fiber, optical waveguide, etc.) is produced by printing one or more glass materials using nozzles fed by heated apparatuses (e.g., syringes or crucibles).

An anti-fog glass includes a glass body configured as a single layer or a multilayer stack; an active anti-fog layer disposed on the glass body and heating up when being provided with power; and a passive anti-fog layer disposed on the glass body and inhibiting fog from forming on the passive anti-fog layer. The passive anti-fog layer is a super hydrophobic coating and/or hydrophilic coating. Both the active anti-fog layer and the passive anti-fog layer are simultaneously disposed on the glass body to inhibit fog from forming. In this way, in a region of the glass body not covered by the active anti-fog layer, the anti-fog function is achieved by the passive anti-fog layer to a certain degree; in addition, in a region where the passive anti-fog layer itself cannot provide a desired anti-fog level, the active anti-fog layer together with the passive anti-fog layer provide a better anti-fog effect.