Provided is a glass sheet (1) with a film, including a laminated film (2), which includes a plurality of films laminated together, formed on a glass sheet (3). The laminated film (2) includes: an inorganic material film (4), which contains at least a noble metal, formed on the glass sheet (3); a plated metal film (5) formed on the inorganic material film; and a metal film (6) formed on the plated metal film (5). The laminated film (2) is black when viewed from a glass sheet (3) side.

The invention provides a transparent substrate including a multiple layer coating stack and the use of same in the manufacture of a double glazing unit. The multiple layer coating stack comprises, n functional metal layer, m; and n plus 1 (n+1) dielectric layer, d, wherein the dielectric layers are positioned before and after each functional metal layer, and wherein n is the total number of functional metal layer in the stack counted from the substrate and is greater than or equal to 3. Each dielectric layer includes one or more layers, characterized in that the geometrical layer thickness of each functional metal layer in the coating stack Gm, is greater than the geometrical layer thickness of each functional metal layer appearing before it in the multiple layer coating stack, that is, Gm.sub.i+1>Gm.sub.i, wherein i is the position of the functional metal layer in the coating stack counted from the substrate. For each dielectric layer d located before and after each functional metal layer m, the optical layer thickness of each dielectric layer (opl.sub.n) is greater than or equal to the optical layer thickness of the dielectric layer (opl.sub.n1) positioned before it in the coating stack with the proviso that twice the optical layer thickness of the first dielectric layer (opl.sub.1) in the coating stack, is less than the optical layer thickness of the second dielectric layer (opl.sub.2) in the coating stack, that is, (2opl.sub.1)<opl.sub.2, and twice the optical layer thickness of the last dielectric layer (opl.sub.n+1) in the coating stack, is greater than the thickness of the optical layer thickness of the penultimate dielectric layer (opl.sub.n), that is, (opl.sub.n)<(opl.sub.n+1)2.

Coated articles include two or more functional infrared (IR) reflecting layers sandwiched between at least dielectric layers. The dielectric layers may be of or including silicon nitride or the like. At least one of the IR reflecting layers is of or including titanium nitride (e.g., TiN) and at least another of the IR reflecting layers is of or including NiCr (e.g., NiCr, NiCrN.sub.x, NiCrMo, and/or NiCrMoN.sub.x).

The purpose of the present invention is to provide a perpendicular magnetic recording medium which uses an Ru seed layer having a (002)-oriented hcp structure, and has a magnetic recording layer including a (001)-oriented L1.sub.0 ordered alloy suitable to perpendicular magnetic recording. The magnetic recording medium of the present invention includes a substrate, a first seed layer containing Ru, a second seed layer containing ZnO, a third seed layer containing MgO, and a magnetic recording layer containing an ordered alloy, in this order, the first seed layer having the (002)-oriented hexagonal closest packed structure.

A material includes a transparent substrate coated with a stack of thin layers including at least one silver-based functional metal layer, including a doping element, of thickness E formed from monocrystalline grains having a lateral dimension D, defined as a line along the grain edge. The D/E ratio is greater than 1.05.

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.

Certain example embodiments relate to Ni-inclusive ternary alloy being provided as a barrier layer for protecting an IR reflecting layer comprising silver or the like. The provision of a barrier layer comprising nickel, chromium, and/or molybdenum and/or oxides thereof may improve corrosion resistance, as well as chemical and mechanical durability. In certain examples, more than one barrier layer may be used on at least one side of the layer comprising silver. In still further examples, a Ni.sub.xCr.sub.yMo.sub.z-based layer may be used as the functional layer, rather than or in addition to as a barrier layer, in a coating.

A material includes a transparent substrate coated with a stack of thin layers including at least one silver-based functional layer, wherein the stack includes a protective coating deposited on top of at least one portion of the functional layer, the protective coating including: a lower protective layer having a thickness of between 1 and 10 nm, a central protective layer based on carbon graphite located on top of the lower protective layer, and an upper protective layer having a thickness of between 1 and 10 nm located on top of the central protective layer.

Disclosed are a pigment having excellent electrical conductivity and corrosion resistance and a method for preparing the same. The method for preparing a pigment according to the present invention comprises the steps of: (a) stirring and dispersing flakes in water to form a suspension; (b) forming a catalyst layer on surfaces of the flakes; and (c) plating the surfaces of the flakes on which the catalyst layer is formed.

Articles comprise a substrate and a conductive film disposed on a surface of the substrate. The conductive film comprises a volume resistivity in a range from about 0.01 Ohm-centimeters to about 10-3 Ohm-centimeters. The conductive film comprises a pencil hardness of about 8H or more. The conductive film comprises a scratch resistance of about 3 Newtons or more. Methods of forming articles comprise disposing a conductive ink on a surface of the substrate. Methods comprise heating the conductive ink at a first temperature from about 100 C. to about 250 C. for a first period of time to form a conductive film. The conductive ink comprises a conductive filler, a reactive, silane-containing binder, and a solvent.