Provided is a display apparatus including a circuit substrate, a light-emitting layer, a polarizing layer, a quarter waveplate, and a bandpass polarizing reflective layer. The light-emitting layer includes a plurality of first light-emitting structures. The first light-emitting structures have a first peak emission wavelength. The polarizing layer is located on a side of the light-emitting layer away from the circuit substrate. The quarter waveplate is disposed between the polarizing layer and the light-emitting layer and overlaps the light-emitting layer and the polarizing layer. The bandpass polarizing reflective layer is disposed between the quarter waveplate and the light-emitting layer and includes a first bandpass polarizing reflective pattern overlapping the first light-emitting structures. A reflectance of the bandpass polarizing reflective pattern for light with a wavelength in a first wavelength range is greater than 20%. The first wavelength range is the peak emission wavelength ±10 nm.

Light-reducing devices that can be removably attached to a window or other panel through which light is able to pass, and methods of using such devices. Such a light-reducing device includes a tinted flexible transparent sheet and a microsuction tape adhered to the tinted flexible transparent sheet. The microsuction tape has a surface with micrometer-sized cavities that create a vacuum when the surface is pressed against a window. At least the surface of the tape is formed of a material that is sufficiently pliable and elastic so that each of the cavities forms a seal against the window and individual vacuums created between the surface and the window releasably secure the light-reducing device to the window when subjected to only the weight of the light-reducing device, but the light-reducing device can be peeled from the window.

An optical isolation element comprising, sequentially: a light control film; a first optical path changing element; and a second optical path changing element. The optical isolation element has an excellent optical isolation ratio, and can be manufactured simply and at low cost. Such an optical isolation element can be applied, for example, to the fields of optical communication or laser optics, security and privacy protection, and members for brightness enhancement in displays or military products requiring hiding and covering, and the like.

All inorganic perovskites for short-wave IR (SWIR) devices having improved chemical stability and long-term stability. Improved methods of making all inorganic perovskites for short-wave IR (SWIR) devices are also disclosed herein.

Laminated light-blocking decorative articles are prepared by applying an aqueous foamed opacifying composition to a non-woven fabric, drying, laminating a decorative fabric to the resulting dry foamed opacifying layer, and densifying that layer to have a thickness that is at least 20% less than before densifying. This operation can be carried out so that non-woven fabric, decorative fabric, and aqueous foamed opacifying composition are supplied in a single-pass, in-line operation to make any desired quantity of a laminated light-blocking decorative article. The applied aqueous foamed opacifying composition has 35%-70% solids and a foam density of 0.1-0.5 g/cm.sup.3. It is composed of (a) porous particles, (b) a binder material, (c) two or more additives comprising at least one foaming surfactant and at least one foam stabilizer, (d) an aqueous medium, and (e) at least 0.0001 weight % of an opacifying colorant that absorbs electromagnetic radiation having a wavelength of 380-800 nm.

A protective film and a display apparatus including the same are disclosed. The display apparatus in the embodiments may include a protective film that is disposed on a display panel and includes a substrate and a light shielding layer being formed in the edge portion of the substrate, which corresponds to a non-display area of the display panel. The light shielding layer may include a first layer and a second layer on the first layer. The first layer may include at least two or more of first patterns that are spaced from each other and a plurality of second patterns that are disposed between at least two or more of the first patterns.

A display panel is provided. The display panel has a display region and a non-display region. The non-display region has an aperture region and a non-aperture region surrounding the aperture region. The display panel includes a plurality of light-emitting elements disposed in the display region. The display panel includes a plurality of first light absorbing patterns and a plurality of second light absorbing patterns disposed in the non-aperture region. The plurality of first light absorbing patterns and the plurality of second light absorbing patterns are configured to absorb different colors of lights.

In example implementations, an apparatus is provided. The apparatus includes a display, an eye barrel, an anti-reflection layer, and a lens. A first end of the eye barrel is coupled to the display. The anti-reflection layer is applied to an inner surface of the eye barrel. The lens is coupled to a second end of the eye barrel.

A prism module manufacturing method includes the following steps of: adjusting a first prism and a second prism to have a predetermined temperature difference; using an adhesive layer to be partially connected between the first prism and the second prism so that there is a gap between the first prism and the second prism, wherein the adhesive layer includes a glue material and a plurality of spacers arranged in the glue material. The invention further provides a prism module and a projection device having the prism module. The prism module and the manufacturing method thereof of the invention avoid the interference problem in the prism module so that the image quality and reliability of the projection device can be improved.

An additive manufacturing system having multiple components includes a high power laser to form a laser beam. A beam dump with a fluid chamber having at least one laser transparent window into which the laser beam is directed is provided. A heat exchanger is connected to the fluid chamber, with the heat exchanger acting to provide useful energy to at least one of the multiple components of the additive manufacturing system. An absorbing fluid can be circulated through both the fluid chamber and the heat exchanger.