A coated article is provided for use in a surveillance window or the like. The coated article is a second surface one-way mirror that allows an observer(s) on an observer side to be able to see an object(s)/subject(s) on the opposite side of the coated article, but a viewer on the opposite side cannot reasonably see through the coated article to view things on the observer side of the coated article. The second surface mirror is designed to have a high glass side visible reflectance (R.sub.GY), and an extremely low film side visible reflectance (R.sub.FY), so that visible transmission (T.sub.vis or TY) of the coated article is lower than the glass side visible reflectance but higher than the film side visible reflectance.

A mirror includes a transparent substrate, at least one metallic reflecting layer and at least one protective paint layer on the back of the mirror. The mirror also includes an overlayer which is a barrier to corrosive elements, such as sulfides and/or chlorides, with a thickness of less than or equal to 6 m which is located on the protective layer. The process for the manufacture of such a mirror is also described.

Certain example embodiments relate to a coated article including a coating formed from a sol that has hydrophobic surface properties. The sol may include a mixture of at least two alkylsiloxane chemicals, with the sol potentially being aged for a certain comparatively short amount of time before being wet-applied to a major substrate surface. The application process may also undergo a certain comparatively short curing process to help provide hydrophobic surface properties. The hydrophobic surface properties help provide anti-soiling functions that are advantageous in a variety of applications including, for example, solar mirror applications.

A dielectric mirror includes a coating having alternating high and low index layers. The mirror coating has no metallic reflective layer, and may have film side and/or glass side visible reflection of from about 50-90% (more preferably from about 60-80% and most preferably from about 65-75%) and visible transmission of from about 10-50% (more preferably from about 20-40%, and most preferably from about 25-35%).

A method for producing a reflector element and a reflector element are disclosed. In an embodiment the method includes depositing a layer sequence on a substrate, wherein the layer sequence includes at least one mirror layer and at least one reactive multilayer system and igniting the reactive multilayer system in order to activate heat input in the layer sequence.

A vehicular interior electrochromic mirror reflective element includes a planar rear interior mirror-shaped glass substrate and a planar front interior mirror-shaped glass substrate. The front glass substrate is shape cut from a planar glass sheet. A perimeter seal establishes an interpane cavity between the rear glass substrate and the planar glass sheet at a respective planar front glass substrate portion of the planar glass sheet. An electrochromic medium is disposed in the interpane cavity. With the rear glass substrate joined with the respective planar front glass substrate portion of the planar glass sheet via the perimeter seal, the planar glass sheet is shape cut at the respective planar front glass substrate portion and the circumferential perimeter cut edges of glass substrates are processed to provide a circumferential rounded perimeter edge of the vehicular interior electrochromic mirror reflective element having a radius of curvature of at least 2.5 mm.

A colored mirror includes a transparent substrate, a reflective metal layer and at least one interface layer between the substrate and the metal layer, wherein the interface layer includes at least one discontinuous metal layer, and at least one overlayer of a dielectric material deposited on the discontinuous layer. The discontinuous metal layer allows the adaptation of the color reflected by the mirror. The nominal thickness thereof and the type of material, as well as the nature and thickness of the dielectric overlayer, play a role in obtaining the color of the mirror.

A dual-surfaced mirror for a mirror wedge illusion. The dual-surfaced mirror includes a reflective material layer, a thin glass layer overlaying a front surface of the reflective material, a dark mask layer overlaying a back surface of the reflective material, and a thick glass support layer coupled to the dark mask layer.

A dielectric mirror includes a coating having alternating high and low index layers. The mirror coating has no metallic reflective layer of Al or Ag in certain example embodiments, and may have film side and/or glass side visible reflection of from about 50-90% (more preferably from about 60-80% and most preferably from about 65-75%) and visible transmission of from about 10-50% (more preferably from about 10-40% or 20-40%) in certain example embodiments.

Certain example embodiments relate to techniques for creating flat laminated mirrors, e.g., for use in concentrating solar power (CSP) applications. In certain example embodiments, the first substrate is a low iron glass substrate. A reflective coating is provided between the first and second substrates. The first and second substrates are laminated together via a radiation curable laminating adhesive with the reflective coating between the substrates. In certain example embodiments the radiation curable laminating adhesive is cured via UV radiation in order to form a laminated reflective article.