Abstract: An optical information recording medium includes a recording layer that absorbs recording light in accordance with its wavelength, the recording light being condensed for information recording, and increases the temperature in the vicinity of a focus so as to form a recording mark and that has properties of increasing a light absorption amount with respect to the wavelength of the recording light by heating performed at a temperature of 120° C. or more.

Abstract: A conductive element includes a base having a first wavy surface, a second wavy surface, and a third wavy surface, a first layer provided on the first wavy surface, and a second layer provided on the second wavy surface. The first layer has a multilayer structure including two or more stacked sublayers, the second layer has a single-layer or multilayer structure including part of the sublayers constituting the first layer, and the first and second layers form a conductive pattern portion. The first, second, and third wavy surfaces satisfy the following relationship: 0?(Am1/?m1)<(Am2/?m2)<(Am3/?m3)?1.8 (Am1: mean amplitude of first wavy surface, Am2: mean amplitude of second wavy surface, Am3: mean amplitude of third wavy surface, ?m1: mean wavelength of first wavy surface, ?m2: mean wavelength of second wavy surface, ?m3: mean wavelength of third wavy surface).

Abstract: An optical system includes an optical element that has a surface on which a plurality of sub-wavelength structure bodies are formed; and an imaging device that has an imaging region which senses light via the optical element, wherein the surface of the optical element has one or two or more sections that scatter incident light and generate scattered light, and wherein a sum total of components of the scattered light reaching the imaging region is smaller than a sum total of components thereof reaching regions other than the imaging region.

Abstract: A conduction element includes a substrate which has a first wave surface and a second wave surface, and a laminate film which is formed on the first wave surface and where two or more layers are laminated, where the laminate film forms a conduction pattern, and the first wave surface and the second wave surface satisfy a relationship below. 0?(Am1/?m1)<(Am2/?m2)?1.

Abstract: An electrically conductive optical element is provided with a substrate having a surface, structures which are convex portions or concave portions in the shape of a cone and which are arranged in large numbers on the surface of the substrate with a minute pitch less than or equal to the wavelength of the visible light, and a transparent, electrically conductive layer disposed on the structures. The aspect ratio of the structure is 0.2 or more, and 1.3 or less, the transparent, electrically conductive layer has a surface following the structures, the average layer thickness Dm1 of the transparent, electrically conductive layer at the top portion of the structure is 80 nm or less, and the surface resistance of the transparent, electrically conductive layer is within the range of 50?/? or more, and 500?/? or less.

Abstract: A conductive optical device includes a base member and a transparent conductive film formed on the base member. A surface structure of the transparent conductive film includes a plurality of convex portions having antireflective properties and arranged at a pitch equal to or smaller than a wavelength of visible light.

Abstract: Provided is a conductive optical device including a substrate having flexibility; structural elements which are constructed with a plurality of convex portions or concave portions with a fine pitch which is equal to or less than the wavelength of visible light arranged on a surface of the substrate; and a transparent conductive layer which is formed on the structural elements, wherein the aspect ratio of the structural elements is equal to or more than 0.1 and equal to or less than 1.8, wherein the transparent conductive layer has a surface emulating the structural elements, and wherein a conductivity with respect to the bending test is maintained.

Abstract: An electroconductive element includes a substrate having a first wavy surface and a second wavy surface, and an electroconductive layer formed on the first wavy surface, wherein the electroconductive layer forms an electroconductive pattern, and the first wavy surface and the second wavy surface satisfy the following relationship: 0?(Am1/?m1)<(Am2/?m2)?1.8. Am1 is a mean amplitude of vibrations of the first wavy surface, Am2 is a mean amplitude of vibrations of the second wavy surface, ?m1 is a mean wavelength of the first wavy surface, and ?m2 is a mean wavelength of the second wavy surface.

Abstract: A transparent conductive element is provided and includes a conductive layer having a first surface and a second surface and a medium layer formed on at least one of the first surface and the second surface. In the transparent conductive element, at least one of the first surface and the second surface is a wave surface with a wavelength shorter than or equal to that of visible light; the ratio (Am/?m) of a mean peak-to-peak amplitude Am to a mean wavelength ?m of the wave surface is 1.8 or less. The mean thickness Dm of the conductive layer is larger than the mean peak-to-peak amplitude Am of the wave surface.

Abstract: A manufacturing method of a laminated body includes applying an energy ray curable resin composition on a base, and causing a rotation surface of a rotation stamper to come into close contact with the energy ray curable resin composition applied on the base during rotation, and irradiating the energy ray curable resin composition with energy rays emitted from one or a plurality of energy ray sources provided in the rotation stamper via the rotation surface so as to cure the energy ray curable resin composition, thereby forming a shape layer onto which concave and convex shapes of the rotation surface are transferred, on the base.

Abstract: In one example embodiment, an optical element includes a base and a large number of structures arranged on a surface of the base. In one example embodiment, the structures are depressions or projections with a conical form. In one example embodiment, the structures are arranged at a pitch shorter than or equal to a wavelength range of light in a use environment and lower portions of the structures adjacent to one another are connected to one another. In one example embodiment, an effective refractive index in a depth direction of the structures gradually increases toward the base and draws an S-shaped curved line.

Abstract: Disclosed herein is an image display apparatus, including: a light source; and a scanning section adapted to scan a light beam emitted from the light source; the scanning section including (a) a first mirror, (b) a first light deflection section, (c) a second mirror, and (d) a second light deflection section; the second light deflection section including an external light receiving face; the second light deflection section having a plurality of translucent films provided in the inside thereof; the translucent films having a light reflectivity R2 at a wavelength of the light beam which satisfies: R2?k×{(P2/t2)×tan(?2)}1/2 where k is a constant higher 0 but lower than 1, P2 an array pitch of the translucent films, t2 a thickness of the second light deflection section, and ?2 an angle formed between the light emitting face and the translucent films.

Abstract: In one example, a conductive optical element is capable of achieving a wide range of surface resistance, and capable of achieving an excellent transmission property. In one example, the conductive optical element includes a substrate having a surface, a number of structures arranged on the surface of the substrate at fine pitches equal to or smaller than a wavelength of a visible light, and a transparent conductive film formed on the structure. In one example, the transparent conductive film has a shape modeled on shapes of the structures. In one example, an aspect ratio of the structures is 0.2 or more and 1.28 or less, and a film thickness of the transparent conductive film is 9 nm or more and 50 nm or less.

Abstract: A method for manufacturing a microfabricated member includes the steps of forming an inorganic resist layer on a stamper having a curved surface, exposing and developing the inorganic resist layer formed on the stamper, so as to form a pattern on the inorganic resist layer, and placing the stamper, which is provided with the pattern on the inorganic resist layer, on an electrode having a curved surface nearly identical or analogous to the curved surface of the stamper and etching the stamper to form an uneven shape on the stamper surface, so as to produce a microfabricated member.

Abstract: An optical element includes a base and a large number of structures arranged on the surface of the base, the structures being projections or depressions. The structures are arranged at a pitch shorter than or equal to a wavelength of light in a use environment. An effective refractive index in the depth direction of the structures gradually increases toward the base and has two or more inflection points.

Abstract: An optical element includes a base and many structures arranged at a fine pitch on a surface of the base, each of the structures being in the form of a projection or a depression, in which the structures constitute a plurality of arc tracks, and the structures in every three adjacent rows of the arc tracks are arranged in a tetragonal lattice pattern or a quasi-tetragonal lattice pattern.

Abstract: A holographic recording medium including a recording layer on a substrate, which records data information in a light interference pattern. In the holographic recording medium, information on a thermal expansion characteristic of a recording material contained in the recording layer and/or information on temperature dependency of the refractive index of the recording material are recorded within the holographic recording medium in advance.

Abstract: An optical element includes a base, and primary structures and secondary structures disposed on a surface of the base, each of the primary structures and secondary structures being a projection or a depression. The primary structures constitute a plurality of rows of tracks on the surface of the base and are periodically repeatedly arranged at a fine pitch equal to or smaller than a wavelength of visible light. The secondary structures are smaller in size than the primary structures, and are provided between the primary structures, in the gaps in the arrangement of the primary structures, or on the surfaces of the primary structures.

Abstract: A holographic recording medium including a recording layer on a substrate, which records data information in a light interference pattern is provided. In the holographic recording medium, information on a thermal expansion characteristic of a recording material contained in the recording layer and/or information on temperature dependency of the refractive index of the recording material are recorded within the holographic recording medium in advance.

Abstract: An optical element having an anti-reflection function includes a base having a first main surface and a second main surface; a plurality of structures composed of projections or recesses and arranged on the first main surface at a fine pitch equal to or less than the wavelength of visible light for which the amount of reflection is to be reduced; and a light-absorbing layer that absorbs the light and that is disposed on the second main surface, wherein the structures are arranged so as to form a plurality of rows of tracks on the first main surface and form a hexagonal lattice pattern, a quasi-hexagonal lattice pattern, a tetragonal lattice pattern, or a quasi-tetragonal lattice pattern, and the structures each have an elliptical cone shape or a truncated elliptical cone shape, the major axis direction of which is a direction in which the tracks extend.