Abstract: There is provided an optical body and a display device that enable wavelength dependence of a reflectance to be reduced and reflection of incident light to be further suppressed, the optical body including: a concave-convex structure formed on a surface of a base material. An average period of concavities and convexities of the concave-convex structure is equal to or shorter than a wavelength belonging to a visible light band. A standard deviation of differences between respective positions of bottom faces of the concavities of the concave-convex structure in a normal direction of a flat surface of the base material and a median of the positions of the bottom faces is greater than or equal to 25 nm.

Abstract: An optical system includes an optical element and an imaging device. The optical element has a surface on which a plurality of sub-wavelength structure bodies are formed. The imaging device has an imaging region which senses light via the optical element. The surface of the optical element has one or two or more sections that scatter incident light and generate scattered light. 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 transfer mold includes a body, a first layer, and a second layer. The body has a projecting-and-recessed surface. The first layer contains an inorganic material and is disposed on the projecting-and-recessed surface of the body. The second layer contains fluorine and is disposed on a surface of the first layer. The average of hardness values of the projecting-and-recessed surface on which the first and second layers are disposed is 30 Hv or higher.

Abstract: There is provided a master for micro flow path creation, a transfer copy, and a method for producing a master for micro flow path creation by which transfer copies having an area with high hydrophilicity can be easily mass-produced, the master for micro flow path creation including: a base material; a main concave-convex portion provided on a surface of the base material and extending in a planar direction of the base material; and a fine concave-convex portion provided on a surface of the main concave-convex portion and having a narrower pitch than the main concave-convex portion. The fine concave-convex portion has an arithmetic average roughness of 10 nm to 150 nm and has a specific surface area ratio of 1.1 to 3.0.

Abstract: An optical unit having an antireflection function includes a wave surface having a wavelength equal to or shorter than a wavelength of visible light. The wave surface has a curved plane which curves in a recessed shape between an apex portion and a bottom portion of the wave surface. An inflection point of an area of a cross section obtained by cutting through the wave surface in a plane perpendicular to a direction of vibration of the wave surface is positioned toward the bottom portion of the wave surface from a center of the vibration.

Abstract: An optical element has a plurality of structures including convex portions or concave portions arranged on a base member surface, wherein the arrangement pitch of the structures is 380 nm to 680 nm and the aspect ratio of the structure is 0.62 to 1.09.

Abstract: A pattern substrate includes a substrate having a surface on which a first area and a second area are formed, and a pattern layer formed at the first area among the first area and the second area. The pattern layer is a wiring pattern layer or a transparent electrode, the first area has a convex/concave shape where a capillary phenomenon occurs, and the convex/concave shape includes an aggregate of a plurality of structures.

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: The present disclosure relates to a solid-state imaging element and an electronic device capable of effectively inhibiting occurrence of reflection and diffraction of light on a light incident surface. A fine uneven structure including a recess and a protrusion is formed with a predetermined pitch on a light incident surface of a semiconductor layer in which photoelectric conversion sections are formed for a plurality of pixels; and an antireflective film is laminated on the fine uneven structure, the antireflective film being formed with a film thickness different for each color of light received by each of the pixels. The pitch of one of the recess and protrusion formed in the fine uneven structure is generally identical in all the pixels, and is 100 nm or less. The present technology is applicable, for example, to a solid-state imaging element.

Abstract: A conductive element includes: a substrate 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 formed on the second wavy surface. 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 (where Am1 is an average width of vibrations of the first wavy surface, Am2 is an average width of vibrations of the second wavy surface, Am3 is an average width of vibrations of the third wavy surface, ?m1 is an average wavelength of the first wavy surface, ?m2 is an average wavelength of the second wavy surface, and ?m3 is an average wavelength of the third wavy surface.

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: 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: There is provided a laminated body, including a substrate and a structure layer which is provided on the substrate and has an anti-reflection function, in which the structure layer includes a plurality of structure bodies and an intermediate layer which is provided between the plurality of structure bodies and the substrate and, in which the intermediate layer satisfies a following relational expression (1). (2?/?)·n(?)·|d?d0|<? (1) (where, ? represents a wavelength of light for a purpose of reduction of reflection, n(?) represents a refractive index of the intermediate layer when the wavelength is ?, d0 represents a thickness of the intermediate layer at a center point, and d represents a thickness of the intermediate layer at any point).

Abstract: An optical element includes an element main body and a plurality of sub-wavelength structures that is provided on a surface of the element main body. The sub-wavelength structures include an energy-ray-curable resin composition, and the element main body is opaque to energy rays for curing the energy-ray-curable resin composition. The surface, on which the plurality of sub-wavelength structures is provided, has a section in which scattered light is generated by scattering incident light, and intensity distribution of the scattered light is anisotropic.

Abstract: An optical element includes a surface on which a plurality of structures is provided. The plurality of structures is provided to be fluctuated in a random direction from a lattice point at an interval which is equal to or shorter than a wavelength of visible light.

Abstract: A conductive element includes: a substrate 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 formed on the second wavy surface. 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 (where Am1 is an average width of vibrations of the first wavy surface, Am2 is an average width of vibrations of the second wavy surface, Am3 is an average width of vibrations of the third wavy surface, ?m1 is an average wavelength of the first wavy surface, ?m2 is an average wavelength of the second wavy surface, and ?m3 is an average wavelength of the third wavy surface.

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: Transparent conductive element includes an optical layer provided with a wave surface that has an average wavelength smaller than or equal to a wavelength of visible light and a transparent conductive layer formed on the wave surface so as to follow the shape of the wave surface. When the average wavelength of the wave surface is ?m and an average amplitude of vibration of the wave surface is Am, the ratio (Am/?m) is 0.2 or more and 1.0 or less; an average angle of sloped surfaces of the wave surface is in the range of 30° or more and 60° or less; and when a thickness of the transparent conductive layer at a highest position of the wave surface is D1 and a thickness of the transparent conductive layer at a lowest position of the wave surface is D3, a ratio D3/D1 is in the range of 0.8 or less.

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: 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.