A sputtering device and method including a chamber, a target disposed within the chamber, and a substrate support including at least a portion consisting essentially of a non-aluminous and non-magnetic metallic material disposed within the chamber. The substrate support may include a carrier and a fixture for holding a substrate. In some embodiments, at least the target-facing surface of the carrier consists essentially of a non-aluminous and non-magnetic metallic material. In some embodiments, the fixture consists essentially of a non-aluminous and non-magnetic metallic material. The sputtering device may be drum sputtering device. The sputtering method may be a magnetron sputtering method.

The present disclosure provides a method for manufacturing a touch panel, the touch panel, a touch screen and a display device. The method includes steps of: forming, on a transparent substrate, a non-opaque film layer with a micro-pattern; and forming a touch panel electrode on the non-opaque film layer. The non-opaque film layer is configured to vanish a shadow of the touch panel electrode.

A transparent structure may have multiple layers, such as an inner layer and an outer layer, which may be formed from glass. The transparent structure may have a large, curved surface with compound curvature and high geometric strain and may include one or more layers. To apply a physical vapor deposition coating with uniform thickness on a curved surface, cathode power may be modulated during the deposition, a mask having an opening with a curvature matching the curved surface may be used, a cathode shape may be varied, the cathodes may sputter the coating outwardly toward the curved surface, a magnetic field may modulate the flux produced by the cathodes, and/or the pressure and/or flow of gas may be adjusted. By modifying the physical vapor deposition coater in one or more of these ways, the coating may have a uniform thickness, and therefore a uniform color, across the curved surface.

A production method for a glass roll includes a start preparation step (S1) of feeding-out a first lead film (LF1) coupled to a starting end portion (GFa) of a first glass film (GF1) from an unwinding device (3) and allowing a winding device (8) to wind the first lead film (LF1 after passing of the first lead film (LF1) through a thermal film-forming device (4),). The start preparation step (S1) includes a temperature increasing step of causing the thermal film-forming device (4) to be increased in temperature to a film-forming temperature. The first glass film (GF1) reaches the thermal film-forming device (4) before the thermal film-forming device (4) is increased in temperature to the film-forming temperature.

Apparatus for depositing one or more variable interference filters onto one or more substrates comprises a vacuum chamber, at least one magnetron sputtering device and at least one movable mount for supporting the one or more substrates within the vacuum chamber. The at least one magnetron sputtering device is configured to sputter material from a sputtering target towards in the mount, thereby defining a sputtering zone within the vacuum chamber. At least one static sputtering mask is located between the sputtering target and the mount. The at least one static sputtering mask is configured such that, when each substrate is moved through the sputtering zone on the at least one movable mount, a layer of material having a non-uniform thickness is deposited on each said substrate.

Described herein are apparatuses for holding a substrate in a near vertical position, wherein the design minimizes substrate sag while allowing the substrate to expand and contract under varying thermal conditions. The apparatus minimizes the stress on the substrate, preventing breakage of or damage to the substrate while it undergoes coating and other thermal processes.

Certain example embodiments of this invention relate to coated articles having a metamaterial-inclusive layer, coatings having a metamaterial-inclusive layer, and/or methods of making the same. Metamaterial-inclusive coatings may be used, for example, in low-emissivity applications, providing for more true color rendering, low angular color dependence, and/or high light-to-solar gain. The metamaterial material may be a noble metal or other material, and the layer may be made to self-assemble by virtue of surface tensions associated with the noble metal or other material, and the material selected for use as a matrix. An Ag-based metamaterial layer may be provided below a plurality (e.g., 2, 3, or more) continuous and uninterrupted layers comprising Ag in certain example embodiments. In certain example embodiments, barrier layers comprising TiZrOx may be provided between adjacent layers comprising Ag, as a lower-most layer in a low-E coating, and/or as an upper-most layer in a low-E coating.

Certain example embodiments of this invention relate to coated articles having a metamaterial-inclusive layer, coatings having a metamaterial-inclusive layer, and/or methods of making the same. Metamaterial-inclusive coatings may be used, for example, in low-emissivity applications, providing for more true color rendering, low angular color dependence, and/or high light-to-solar gain. The metamaterial material may be a noble metal or other material, and the layer may be made to self-assemble by virtue of surface tensions associated with the noble metal or other material, and the material selected for use as a matrix. An Ag-based metamaterial layer may be provided below a plurality (e.g., 2, 3, or more) continuous and uninterrupted layers comprising Ag in certain example embodiments. In certain example embodiments, barrier layers comprising TiZrOx may be provided between adjacent layers comprising Ag, as a lower-most layer in a low-E coating, and/or as an upper-most layer in a low-E coating.

Certain example embodiments of this invention relate to coated articles having a metamaterial-inclusive layer, coatings having a metamaterial-inclusive layer, and/or methods of making the same. Metamaterial-inclusive coatings may be used, for example, in low-emissivity applications, providing for more true color rendering, low angular color dependence, and/or high light-to-solar gain. The metamaterial material may be a noble metal or other material, and the layer may be made to self-assemble by virtue of surface tensions associated with the noble metal or other material, and the material selected for use as a matrix. An Ag-based metamaterial layer may be provided below a plurality (e.g., 2, 3, or more) continuous and uninterrupted layers comprising Ag in certain example embodiments. In certain example embodiments, barrier layers comprising TiZrOx may be provided between adjacent layers comprising Ag, as a lower-most layer in a low-E coating, and/or as an upper-most layer in a low-E coating.

A wavelength-converting element includes a substrate and a wavelength-converting layer. The wavelength-converting layer is disposed on the substrate. The wavelength-converting layer includes a first inorganic binder and a wavelength-converting material. The wavelength-converting material is mixed with the first inorganic binder. The first inorganic binder includes a first alcohol-soluble inorganic binder or a first water-soluble inorganic binder. A projection apparatus using the wavelength-converting element and a manufacturing method of the wavelength-converting element are also provided.