The present invention relates to a layer system, comprising a metallic substrate (1) having the following layers applied on a side (A) thereof from the inside to the outside in the specified order: 4) a layer composed of a material selected from among substoichiometric oxides and oxynitrides of titanium and zirconium or from among metals, selected from among titanium, zirconium, molybdenum, platinum, and chromium or an alloy using one of these metals or of at least two of these metals, 5a) a layer composed of a nickel alloy having chromium, aluminum, vanadium, molybdenum, cobalt, iron, titanium, and/or copper as an alloying partner, or composed of a metal selected from among copper, aluminum, chromium, molybdenum, tungsten, tantalum, titanium, platinum, ruthenium, rhodium, and alloys using one of these metals, or of at least two of these metals, or composed of iron, steel or stainless steel, provided the layer may only consist of aluminum if the reflector layer 6) is formed of aluminum and that, in this case, the aluminum of layer 5a) has been sputtered, 6) an optically dense, high-purity metal reflector layer, 7) a layer selected from among substoichiometric oxides of titanium, zirconium, hafnium, vanadium, tantalum, niobium or chromium and from among metals selected from among chromium, titanium, zirconium, hafnium, vanadium, niobium, tantalum, tungsten, molybdenum, rhodium, and platinum and alloys using one of these metals or at least two of these metals, 9) a layer having a low refractive index (“LI layer”) in relation to a directly adjoining layer 10) (“HI layer”), and 10) a layer directly adjoining layer 9) and having a higher refractive index (“HI layer”) in relation to layer 9) (“LI layer”). The layer system can be used, e.g. as a surface reflector, preferably in applications with LEDs, particularly MC-COB for LEDs, as a solar reflector or as a laser mirror, in particular for color wheels in DLP laser projectors.

Provided are a metasurface primary mirror, a metasurface secondary mirror, a method for manufacturing a metasurface primary mirror, a method for manufacturing a metasurface secondary mirror, and an optical system. The metasurface primary mirror, manufactured by using the method for manufacturing a metasurface primary mirror, includes a transparent substrate which includes a primary mirror metasurface pattern on the transparent substrate. The primary mirror metasurface is configured to satisfy a primary mirror phase distribution such that incident light reflected by a metasurface secondary mirror onto the metasurface primary mirror is reflected and focused.

A multilayer stack displaying a red omnidirectional structural color. The multilayer stack includes a reflector layer, a dielectric layer extending across the reflector layer, and an absorbing layer extending across the dielectric layer. The dielectric layer reflects more than 70% of incident white light that has a wavelength greater than 580 nanometers (nm). In addition, the absorbing layer absorbs more than 70% of the incident white light with a wavelength less than 580 nm. In combination, the reflector layer, dielectric layer, and absorbing layer form an omnidirectional reflector that reflects a narrow band of electromagnetic radiation with a center wavelength between 580-680 nm, has a width of less than 200 nm wide and a color shift of less than 100 nm when the reflector is viewed from angles between 0 and 45 degrees.

The disclosure is directed to a highly reflective multiband mirror that is reflective in the VIS-NIR-SWIR-MWIR-LWIR bands, the mirror being a complete thin film stack that consists of a plurality of layers on a selected substrate. In order from substrate to the final layer, the mirror consists of (a) substrate, (b) barrier layer, (c) first interface layer, (d) a reflective layer, (e) a second interface layer, (f) tuning layer(s) and (g) a protective layer. In some embodiments the tuning layer and the protective are combined into a single layer using a single coating material. The multiband mirror is more durable than existing mirrors on light weight metal substrates, for example 6061-Al, designed for similar applications. In each of the five layer types, methods and materials are used to process each layer so as to achieve the desired layer characteristics, which aid to enhancing the durability performance of the stack.

Embodiments described herein provide for terahertz tags and methods of making and using them. A tag may include a terahertz reflective material; and a saturated hygroscopic material positioned on the terahertz reflective material. A tag may include a terahertz reflective material; and an anhydrous hygroscopic material positioned on the terahertz reflective material. A humidity sensor may include a terahertz reflective material; and an anhydrous hygroscopic material positioned on the terahertz reflective material. A temperature sensor may include a terahertz reflective material; an anhydrous hygroscopic material positioned on the terahertz reflective material; and a polymer overlay having thermally controlled water permeability disposed on the anhydrous hygroscopic material. Some embodiments relate to a tag identification device configured to transmit an incident signal toward the tag, and to receive a reply signal from the tag in response to the incident signal.

This disclosure relates to a vanity mirror for a vehicle, such as a motor vehicle. An example vanity mirror includes a layer of shatter resistant material, a layer of metallic plating attached directly to the layer of shatter resistant material, a layer of adhesive material, and a glass layer attached to the layer of metallic plating via the layer of adhesive material. The disclosed vanity mirror is relatively easy to manufacture and performs well even under extreme temperature conditions (i.e., as low as −40 and as high as 120° C.) without exhibiting deformations such as bumps, cracks, or other distortions.

A light-receiving device includes: a plurality of light-receiving elements arranged in a row on a main surface of a substrate and a first reflection surface and a second reflection surface formed on the substrate to extend in the arrangement direction with the row of the plurality of light-receiving elements interposed therebetween. Each of the first reflection surface and the second reflection surface includes an inclined surface forming one flat surface formed from a main surface of the substrate on which each light-receiving element is formed to a back surface side of the substrate.

A composite pane for a head-up display, includes a first pane having a first surface and a second surface, a second pane having a first surface and a second surface, and a thermoplastic intermediate layer, which is arranged between the second surface of the first pane and the first surface (III) of the second pane, an HUD region, and a first coating for reflecting p-polarized radiation and has exactly one electrically conductive layer based on silver, wherein a second coating for reducing the total transmitted thermal radiation is provided.

An optical element mounting package includes an optical component and a base. The optical component reflects light. The base has a recess. In the recess, a first mounting portion and a second mounting portion are provided. On the first mounting portion, an optical element is to be mounted. On the second mounting portion, the optical component is mounted. The optical component includes a reflective surface and a transmission film on the reflective surface. A front surface of the transmission film is inclined relative to the reflective surface.

Disclosed are various methods for creating optical elements through holographic fabrication. One method includes positioning a reflector in an optical path, disposing a first substrate proximal to the reflector along the optical path, disposing a first photosensitive film on the side of the first substrate facing the reflector, transmitting a light beam at a first polarization from a light source along the optical path, reflecting the light beam off the reflector, wherein the reflected light beam has a second polarization, receiving the reflected light beam through the first film and the first substrate, and applying a liquid crystal layer to the first photosensitive film to reproduce the alignment pattern of the first film on the liquid crystal layer.