Abstract: A spectral reflectance in the entire visible wavelength range may be decreased to decrease inconveniences in an image such as flare or ghost. A non-reflective periodic layer including a large number of fine uneven periodic structure bodies is formed on a substrate, and a neutral density (“ND”) film is formed on the other surface of the substrate by vacuum deposition, to improve an anti-reflection function. Regarding a beam entering the ND filter, the MgF2 film of the formed ND film suppresses the spectral reflectance at the boundary of the atmosphere and the ND film and at the boundary of the ND film and the substrate. The non-reflective periodic layer decreases the reflectance at the boundary of the substrate and the atmosphere.

Abstract: A sacrificial limiter filter may include a substrate and a metal nano-coating and/or a polymer/carbon allotrope coating. The sacrificial limited filter may transmit optical radiation having desired frequencies and/or intensities while blocking optical radiation having undesired frequencies and/or intensities.

Abstract: A plasmonic optical spectrum filtering device is provided that filters electromagnetic waves by optical resonance, for example, by selective conversion between the free-space waves and spatially confined modes in plasmonic nano-resonators. Frequency-selective transmission and reflection spectra are engineered and can be used as spectrum filters for display and imaging applications. A thin film stack color filter is further disclosed, which can be designed to either function as a transmission color filter with efficiency twice that of conventional colorant based color filter; or as a reflective color filter for display devices (e.g., used in an energy harvesting reflective display). In other variations, a novel reflective colored display is viewable under direct sunlight, and can simultaneously harvest both incident light and generate electrical power. Methods of making such plasmonic optical spectrum filtering devices are also provided.

Abstract: Provided are multi-component films useful as optical display filters. The optical display filters include a multi-layer stack that contains at least one organic layer. The filters have high visible light transmittance, low visible light reflection, and provide electromagnetic interference shielding.

Abstract: The disclosure is directed to a coating consisting of a binary metal fluoride coating consisting a high refractive index metal fluoride layer on top of a substrate, a low refractive index metal fluoride layer on top of the high refractive index layer and layer of SiO2 or F—SiO2 containing 0.2 wt % to 4.5 (2000 ppm to 45,000 ppm) F on top of the low refractive index layer. In one embodiment the F content of F—SiO2 is in the range of 5000 ppm to 10,000 ppm F. The high index and low index materials are each deposited to a thickness of less than or equal to 0.9 quarter wave, and the capping material is deposited to a thickness in the range of 5 nm to 25 nm. The disclosure is also directed to optical elements having the foregoing coating and a method of making the coating.

Abstract: An optical laminated body includes: a dielectric layer having a surface exposed to air; a metallic layer that has an interface with the dielectric layer, and contains at least Ag; and a laminated body that has an interface with the metallic layer and includes one or more low-refractive-index layers and one or more high-refractive-index layers, wherein a reflectance in a wavelength region of 460 to 650 nm is 0.1% or less.

Abstract: The present invention relates to an optical lens, in particular for use as a spectacle lens, having a lens element and a coating for producing an antistatic effect, said coating being applied onto the lens element and having a plurality of layers. Further, the antistatic effect is provided by two layers adjoining one another, wherein at least one of the two layers adjoining one another is formed in a non-stoichiometric fashion. Furthermore, the present invention relates to a method for producing a corresponding optical lens.

Abstract: Retroreflective elements and articles that include such elements. The retroreflective elements (100) include a solid spherical core (110) having an outer surface. A first complete concentric optical interference layer (112) overlays the outer surface of the core providing a first interface between the core and the first optical interference layer, and a second complete concentric optical interference layer (122) overlays the first optical interference layer to provide a second interface between the first optical interference layer and the second optical interference layer. In some embodiments, a third complete concentric optical interference layer overlays the second optical interference layer to provide a third interface between the second optical interference layer and the third optical interference layer.

Abstract: An interference filter includes first and second reflecting films opposed to each other across a gap, the first and second reflecting films include an Ag—Sm—Cu alloy film or an Ag—Bi—Nd alloy film, the Ag—Sm—Cu alloy film includes 0.1 atomic %?Sm?0.5 atomic %, and 0.1 atomic %?Cu and ?0.5 atomic %, and Sm+Cu?1.0 atomic %, the Ag—Bi—Nd alloy film includes 0.1 atomic %?Bi?3.0 atomic %, and 0.1 atomic %?Nd?5.0 atomic %, and the thickness of the Ag—Sm—Cu alloy film or the Ag—Bi—Nd alloy film is ?10 nm and ?40 nm.

Abstract: An optical element has a first optical layer; a reflective layer; and a second optical layer. The reflective layer includes at least five layers of high refractive-index layers and metal layers alternately laminated. When a thickness L of the entire reflective layer is 80 nm, a ratio ? of an optical thickness of the entire metal layers to that of the entire high refractive-index layers and a ratio ? of an optical thickness of a third high refractive-index layer to that of a first high refractive-index layer are included in a first region, when the thickness L is 90 nm, the ratios ? and ? are included in a second region, and when the thickness L is 80 to 90 nm, the ratios ? and ? are included in a space enclosed by the first region, the second region, and straight lines derived from these regions.

Abstract: An optical element for reflecting solar light has excellent weather resistance, and furthermore, a high reflectance in a wide band. When solar light enters an optical element (OE), light (L1) in a short wavelength band among the solar light is reflected by a dielectric multilayer film (DF). Other light (L2) in longer wavelength bands are passed through the dielectric multilayer film (DF), then a base material (SS), and reflected by a metal deposition film (MV) to pass through the base material (SS) and the dielectric multilayer film (DF). Thus, high reflectance in a wide band is ensured.

Abstract: An anti-reflection film which has not only sufficient anti-reflection properties and antistatic properties but also excellent optical properties is provided. The anti-reflection film includes an antistatic hard coat layer and a low refractive index layer on a transparent substrate, the antistatic hard coat layer containing conductive particles and a binder matrix, the antistatic hard coat layer including a mixed layer in which the transparent substrate component and the binder matrix blend together with a gradient and a localized layer, the mixed layer being optically indistinguishable and the localized layer being optically distinguishable, and the localized layer having an optical thickness of 50-400 nm.

Abstract: The invention relates to a glass substrate with interference colouration for a facing panel, comprising a glass sheet covered on one of the faces thereof by a stack of coatings including successively at least: a first transparent coating made from a dielectric material having an optical thickness at least greater than or equal to 5 nm and at most less than or equal to 258 nm; a semi-transparent functional coating having a geometric thickness at least greater than or equal to 0.1 nm and at most less than or equal to 50 nm; a second transparent coating made from a dielectric material and having an optical thickness at least greater than or equal to 20 nm and at most less than or equal to 300 nm; and a coating providing opacity or quasi-opacity and having a geometric thickness at least greater than or equal to 30 nm.

Abstract: On the light-entering surface side of a base material 10, a coating layer 11 in which a high-refractive layer and a low-refractive layer are sequentially disposed alternately on one on the other is provided for blocking infrared radiation. One of the high-refractive layers is configured by an ITO film 11a so that the conductivity is increased on the surface of the coating layer. Herein, in view of preventing, to a further extent, the attachment of dirt and dust by providing the conductivity to the surface of the coating layer, it is desirable if the outermost high-refractive layer is made of a transparent conductive material. Moreover, it is desirable if the total layer thickness is 140 nm or smaller for the refractive layers formed outside of the high-refractive layer made of the transparent conductive material.

Abstract: An optical layered body wherein the additive amount of the antistatic agent can be reduced leading to a cost reduction while achieving high antistatic property simply and at a low cost. An optical layered body including an optical layered body comprising a light-transmitting substrate and at least a hard coat layer and a low refractive index layer, firmed on the light-transmitting substrate, wherein 1) the low refractive index layer is formed on the outermost surface, and 2) the low refractive index layer contains an antistatic agent.

Abstract: The present invention relates to an optical imaging system communicatively connected to a microwave energy producing source wherein the combination provides for increases in chemical reaction times and the ability to monitor the reactions in real time with sufficient resolution to view the location of intracellular components labeled with luminescent molecules as well as interaction with other biomolecules and responses to localized environmental variables in living cells and tissues during the application of a microwave field.

Abstract: The present invention discloses a progressive-refractivity antireflection layer and a method for fabricating the same to eliminate light reflection occurring in an interface. The present invention is characterized in being fabricated via depositing a first material and a second material, and having a refractivity (neff) gradually varying with a thickness thereof and ranging between a refractivity (n1) of the first material and a refractivity (n2) of the second material. No matter at what thickness the refractivity (neff) of the antireflection layer is measured, the refractivity (neff) meets an effective medium theory expressed by an equation: neff={n12f+n22(1?f)}1/2, wherein f is a filling ratio of the first material of the antireflection layer.

Abstract: A photonic crystal structure includes a nano structure layer including a plurality of nano particles of various sizes, and a photonic crystal layer on the nano structure layer. The plurality of nano particles are spaced apart from each other. The photonic crystal layer has a non-planar surface, and is configured to reflect light of a particular wavelength.

Abstract: The present disclosure provides a touch stack-up structure, which can be applied in a touch panel to make the panel have excellent appearance and reliability. An embodiment of the present disclosure provides a touch stack-up structure that comprises sequentially forming a patterned transparent conductive layer, a first transparent insulation layer with low refractive index, a second transparent insulation layer with high refractive index, and an optical clear adhesive on a transparent substrate.

Abstract: Provided is a highly reliable solar collecting system. Since a concave minor has a reflection film on a base material on the side opposite to the side of a solar light incoming surface, peeling, breaking and the like are suppressed by protecting the reflection film by the base material, even when a dropping material is brought into contact with the side of the reflection film with impact or accumulated dropped materials are periodically cleaned. As an elliptical mirror has a reflection film on the base material on the side of the solar light incoming surface, even when solar light having large energy enters, the solar light is reflected by the reflection surface before reaching the base material and there is a small possibility of having the base material heated.

Abstract: An optical component emits or transmits laser light of a wavelength of 460 nm or less, and a first coating formed from a dielectric film is applied upon at least a part of the surface thereof, and a second coating B formed from a dielectric film containing a noble metal or platinum group element is applied upon the first coating.

Abstract: The present invention discloses a conductive film including a substrate, a hard coated layer, a first refraction layer, a second refraction layer, and a transparent conductive layer. The hard coated layer may be disposed on the substrate with the silicon-based material accounting for certain percentages of the weight thereof. Placement of the first refraction layer, the second refraction layer, and the transparent conductive layer may be arranged in a predetermined order. The transparent conductive layer may cover parts of the second refraction layer. When a light enters into the transparent conductive layer and the second refraction layer with an incident angle, the light may be associated with a first reflectance and a second reflectance, respectively. The difference between the first reflectance and the second reflectance may be lower than a first threshold value for eliminating the display difference between an etched and a non-etched area of the conductive film.

Abstract: Provided are multi-component films useful as optical display filters. The films include a transparent substrate, a nucleation layer, an electrically-conductive layer, a barrier layer, and a dielectric layer. The films can provide high visible transmission, are corrosion-resistant, and can provide shielding from electromagnetic interference (EMI shielding). The optical display filters are useful as components of active optical devices such as display panels including liquid crystal display panels such as those used on mobile hand-held phones.

Abstract: Provided are a filter having a metamaterial structure and a method of manufacturing the filter. The filter includes a first dielectric layer, a first fishnet pattern having one or more first holes partially exposing the first dielectric layer, a second dielectric layer covering the first fishnet pattern and the first dielectric layer, a plurality of reverse patterns having the same shape as those of the first holes, and disposed on the second dielectric layer over the first holes, and a third dielectric layer covering the reverse patterns and the second dielectric layer.

Abstract: A transparent conductive element includes: an optical layer on which a wave surface with an average wavelength equal to or less than a wavelength of visible light is provided; and a transparent conductive layer that is formed on the wave surface so as to follow the corresponding wave surface. Assuming that the average wavelength of the wave surface is ?m and the average width of oscillation of the wave surface is Am, a ratio of (Am/?m) is 0.2 or more and 1.0 or less. The average wavelength ?m of the wave surface is 140 nm or more and 300 nm or less. The film thickness of the transparent conductive layer at a position, at which the height of the wave surface is maximized, is 100 nm or less. The area of a planar portion of the wave surface is 50% or less.

Abstract: A visible wavelength range proximity sensor includes a visible light emitter with a peak wavelength in a visible wavelength range, and a plasmonic ambient light sensor, where a proximity sensing mode and an ambient light sensing mode are time multiplexed.

Abstract: A transparent electromagnetic wave-shielding filter, containing a support, a conductive layer provided on the support, and a hard coat layer provided on the conductive layer, wherein the conductive layer is formed by subjecting an emulsion layer which contains a silver halide and a binder and is coated on the support, to exposure and developing process, wherein the hard coat layer is formed by coating a coating liquid for forming the hard coat layer with a solvent on the conductive layer, and wherein the emulsion layer contains a compound soluble in the solvent of the coating liquid for forming the hard coat layer.

Abstract: The present invention provides an anti-reflection film having excellent optical property, excellent excoriation resistance, and antistatic function at low production costs. The present invention includes an anti-reflection film in which a localized layer and a low refractive index layer are stacked in this order on at least one surface of a transparent substrate, the localized layer is stacked with an intermediate layer, a hard coat layer, an antistatic layer containing a conductive material, and a leveling layer containing a leveling material in this order, which are localized, at least from the side of the transparent substrate, and the leveling material contains at least a fluorocompound or a compound which has a siloxane bond.

Abstract: A article includes a substrate and a metal dielectric reflective film. The metal dielectric reflective film is formed on the substrate, the metal dielectric reflective film includes a dielectric multiple layer and a metal layer. The dielectric multiple layer includes a first layer, a second layer, a third layer, and a fourth layer arranged in the order written and stacked one on another. The first and third layers comprised of a low refractive index material, the second and fourth layers comprised of a high refractive index material. The metal layer is disposed on the fourth layer.

Abstract: A plasmonic Fabry-Perot filter includes a first partial mirror and a second partial mirror separated from the first partial mirror by a gap. At least one of the first partial mirror or the second partial mirror includes an integrated plasmonic optical filter array.

Abstract: Disclosed is a transparent touch screen construction that includes a pattern of layer stacks disposed on a substrate. The layer stacks each include a transparent conductor layer and an intermediate layer positioned between the substrate and the transparent conductor layer. The intermediate layer has a refractive index that is lower than that of the transparent conductor layer and that of the substrate. The construction of the layer stacks reduces the difference in visible light transmission between the areas of the substrate covered by the stacks and the areas of the substrate left exposed by the stacks. Also disclosed are methods for reducing the visibility of a patterned transparent conductor in a touch screen by disposing an intermediate layer pattern between a substrate and a transparent conductor pattern, the intermediate layer pattern and transparent conductor pattern being coincident.

Abstract: The invention concerns a security element (1) and a value-bearing document safeguarded by such a security element. The security element (1) includes a strip-form multi-layer body (10) with a carrier film (11) and at least one decorative layer (12), as well as a first and a second adhesive layer (14, 15). The first adhesive layer (14) is provided on a first surface of the multi-layer body (10). The second adhesive layer (15) is provided on an opposite second surface of the multi-layer body. The security element has two or more first regions (21) in which the first adhesive layer (14) respectively covers the first surface of the multi-layer body and two or more second regions (22) in which the second but not the first surface of the multi-layer body is respectively covered by the second and the first adhesive layer respectively and in which a surface structure is respectively formed in the first surface. First and second regions (21, 22) are in this case arranged in mutually juxtaposed adjacent relationship.

Abstract: A decorative coating and a method for forming a decorative coating on a substrate (2). The decorative coating comprises an absorbing film (1) to attenuate the transmission of visible light through the coating. The method comprises the steps of bringing the substrate (2) into a reaction space, and depositing the absorbing film (1) on the substrate (2). Depositing the absorbing film (1) on the substrate comprises the steps of forming a preliminary deposit of transition metal oxide on the deposition surface and subsequently purging the reaction space, and treating the deposition surface with an organometallic chemical comprising first metal and subsequently purging the reaction space. The steps of forming the preliminary deposit and treating the deposition surface are alternately repeated to increase absorption of the absorbing film (1).

Abstract: An anti-reflection film with low production costs, excellent anti-reflection performance or excellent optical properties free from interference variation, high abrasion resistance, and antistatic function to prevent dust adhesion is demanded. In the present invention, the problem to be solved is to provide an anti-reflection film having low production costs, excellent optical property and excellent abrasion resistance and antistatic function. The present invention provides an anti-reflection film in which a localized layer and a low refractive index layer are laminated in this order on at least one surface of a transparent base, and the localized layer is constituted to have an intermediate layer, a hard coat layer, an antistatic layer containing a conductive material and a leveling layer containing a leveling material that are laminated as localized in order from at least the side of the transparent base.

Abstract: A plate member for touch panel and a method of manufacturing the same are provided. The plate member for touch panel includes: a base substrate; a first intermediate layer disposed on a first side of the base substrate and having a first refractive index; a second intermediate layer disposed on the first intermediate layer and having a second refractive index lower than the first refractive index; and a transparent conductive layer disposed on the second intermediate layer.

Abstract: The present invention relates to a thin-film element (30) having an interference layer structure for security papers, value documents and the like, having at least two semitransparent absorber layers (34, 38) and at least one dielectric spacing layer (36) arranged between the at least two absorber layers. According to the present invention, it is provided that the two absorber layers (34, 38) are each formed from a material having a complex refractive index N whose real part n and imaginary part k differ at least in a portion of the visible spectral range by a factor of 5 or more.

Abstract: A reference wafer maintains laser accuracy and calibrates a camera and a laser of a semiconductor equipment. The reference wafer includes a first anti-reflection layer, an adhesive layer, a light absorption layer and a second anti-reflection layer that are stacked over a substrate, a light reflection layer formed over the second anti-reflection layer, and a protection layer formed over the light reflection layer.

Abstract: Antireflective transparent EMI shielding optical filters are provided that can be laminated to optical display devices using optically clear adhesives. The provided filters include electrically-conductive metal or metal alloy layers that can be continuous and patterned or unpatterned. Also included are methods of making the provided filters and touch sensors made using the provided filters.

Abstract: An optically transmissive structure for laser protection is provided including a plurality of metallic layers of material interspersed with a plurality of dielectric layers of material. The metallic layers are interposed with the dielectric layers; the metallic layers include individual layers each having a thickness smaller than a skin depth of the metal at a selected wavelength; and the dielectric layers separating two metallic layers have a thickness equal to or smaller than the selected wavelength in the dielectric layer of material. A method for fabricating the above structure is also provided. An optically transmissive structure for laser protection including a plurality of metal layers interposed with dielectric material layers is also provided. A transmittance of the structure is greater than fifty percent (50%) for an incident light having a wavelength of 550 nm; and an optical density of the structure is greater than two (2) for an incident light having a wavelength between 1000 nm and 1400 nm.

Abstract: The invention relates to an optical article having antireflection properties, optionally antistatic properties, having a high thermal and abrasion resistance, as well as the method for producing the same. The article of the invention comprises a substrate and, starting from the substrate: a sub-layer comprising a SiO2-based layer, said SiO2-based layer having a thickness greater than or equal to 75 nm et free from Al2O3; and a multilayered antireflection coating comprising a stack consisting in at least one high refractive index layer and at least one low refractive index layer, all the low refractive index layers of which comprising a mixture of SiO2 and Al2O3, and the high refractive index layers of which are not layers that do absorb in the visible region comprising a substoichiometric titanium oxide and reducing the relative visible light transmission factor (Tv) of the optical article by at least 10% as compared to a same article without any of said visible light absorbing layers.

Abstract: An optical film having a transparent support having thereon at least a hardcoat layer and an antistatic layer in this order, wherein the hardcoat layer and the antistatic layer are formed by simultaneously coating compositions for forming respective layers, the antistatic layer comprises at least (A) an electrically conductive organic compound and (B) a polyfunctional monomer having three or more polymerizable groups, a content of an inorganic oxide fine particle in the antistatic layer is less than 10 weight % based on an entire solid content of the antistatic layer, and a common logarithmic value (LogSR) of surface resistivity SR (?/sq) on the antistatic layer side with respect to the transparent support is 13 or less.

Abstract: A reflective optical element exhibits an increase in the maximum reflectivity at operating wavelengths in the extreme ultraviolet or soft x-ray wavelength range. A first additional intermediate layer (23a, 23b) and a second additional intermediate layer (24a, 24b) are provided between the absorber layer (22) and the spacer layer (21), wherein the first additional intermediate layer increases the reflectivity and the second additional intermediate layer (24a,b) prevents chemical interaction between the first additional intermediate layer (23a,b) and the adjoining spacer layer (21) and/or the absorber layer (22).

Abstract: An interference filter is provided in which a fixed mirror and a movable mirror of the interference filter are selected from an Ag—Au alloy film, an Ag—Cu alloy film, an Ag—Au—Cu alloy film, an Ag—Si—Cu alloy film, an Ag—P—Cu alloy film, an Ag—P—In—Cu alloy film, an Ag—Te—Cu alloy film, an Ag—Ga—Cu alloy film, and an Ag—In—Sn alloy film.

Abstract: An interference filter having a plurality of layers and a spectrum as a function of angle of observation is combined with a metameric element adjacent the interference filter and appearing to have a same color as the interference filter at at least one angle of observation and a contrasting color as said interference filter at least one other angle of observation. A plurality of interference filter layers, including a metallic layer, can be provided on a support structure for the layers. The support structure is then adapted to allow the layers to be seen from a top and a bottom side, with the layers being adapted to have different spectra as a function of angle of observation in reflection and transmission.

Abstract: Provided are a reflective structure, a display apparatus including the reflective structure, and methods of manufacturing the reflective structure and the display apparatus. The reflective structure may include a reflective layer having a multiple uneven structure. The reflective layer may have a curved surface as a result of a plurality of first uneven portions, and wherein the curved surface may has a plurality of second uneven portions having a scale less than that of the first uneven portions. The plurality of first uneven portions may have a micro-scale size, and the plurality of second uneven portions may have a nano-scale size. The reflective layer may be arranged on a lower structure including a plurality of nanoparticles. A flexible material layer may be formed on the reflective layer.

Abstract: A transparency includes a first ply having a first visible light transmission and a second ply having a second visible light transmission, with the first visible light transmission being greater than the second visible light transmission. A solar control coating is located between the first ply and the second ply. The solar control coating has a first infrared reflective metallic layer, a second infrared reflective metallic layer and a third infrared reflective metallic layer. The first infrared reflective metallic layer is thicker than the second infrared reflective metallic layer and the second infrared reflective metallic layer is thicker than the third infrared reflective metallic layer.

Abstract: A material of variable emissivity includes a first metallic layer having a first aperture, a second metallic layer having a second aperture, and a variable dielectric layer interposed between the first metallic layer and the second metallic layer.

Abstract: An optical element has a first optical layer; a reflective layer; and a second optical layer. The reflective layer includes at least five layers of high refractive-index layers and metal layers alternately laminated. When a thickness L of the entire reflective layer is 80 nm, a ratio ? of an optical thickness of the entire metal layers to that of the entire high refractive-index layers and a ratio ? of an optical thickness of a third high refractive-index layer to that of a first high refractive-index layer are included in a first region, when the thickness L is 90 nm, the ratios ? and ? are included in a second region, and when the thickness L is 80 to 90 nm, the ratios ? and ? are included in a space enclosed by the first region, the second region, and straight lines derived from these regions.

Abstract: An image screen includes a transparent substrate, a metal film, and an optical reflective stack layer. The metal film is disposed on a first surface of the transparent substrate, having a thickness and a set of material characteristic constants being predetermined. The optical reflective stack layer is disposed over the metal layer. The metal film and the optical reflective stack layer function together to selectively reflect a light with a portion of wavelength. In addition, according to the need, a diffusion micro-structure layer can be disposed on a second surface of the transparent substrate. Further for example, another reflective layer or optical absorbing layer can be further disposed on another surface of the optical reflective stack layer. The reflective layer can be, for example, a metal film.

Abstract: The present invention relates to a method of imaging structures and features using plasmonic emissions from metallic surfaces caused by chemiluminescence based chemical and biological reactions wherein imaging of the reactions is enhanced by the use of microwave energy and further enhanced by using metallic geometric structures for spatially and temporally controlling the biological and chemical reactions.