Abstract: An electrolyte membrane (1) includes a base material layer (1) containing a hydrocarbon-based electrolyte as a main component, and a surface layer (5) laminated with the base material layer (1). The surface layer (5) is a layer containing, as a main component, a polymeric material having a hydroxyl group and a proton conductive group. The polymeric material that constitutes the surface layer (5) contains, for example, a first polymer having a hydroxyl group, and a second polymer having a proton conductive group. A matrix is formed by cross-linking the first polymer, and the second polymer can be held in the matrix.

Abstract: A method of manufacturing a proton-conductive polymer electrolyte membrane using polyvinyl alcohol (PVA) as a base material and having excellent proton conductivity and methanol blocking properties is provided. The method includes: heat-treating a precursor membrane including PVA and a water-soluble polymer electrolyte having a proton conductive group to proceed crystallization of the PVA; and chemically crosslinking the heat-treated precursor membrane with a crosslinking agent reactive with the PVA, to form a polymer electrolyte membrane in which a crosslinked PVA is a base material and protons are conducted through the electrolyte retained in the base material. The content of a water-soluble polymer except the PVA and the water-soluble polymer electrolyte in the precursor membrane is in a weight ratio of less than 0.1 with respect to the PVA.

Abstract: In an optical touch panel 20 using optical waveguides, a pigment mixture consists of at least 2 kinds of pigments is contained in a clad 14. The pigment mixture has stronger absorption of light in a visible range than in a near-infrared range. Signal beams in the near-infrared range are hardly absorbed, although ambient light having entered the clad 14 in the visible range is strongly absorbed. This makes it possible to significantly reduce ambient light in the visible range to enter cores 12 after passing through the clad 14 and it is possible to use the optical touch panel 20 outdoors, either.

Abstract: An optical touch panel 10 includes: a coordinate input region 11; a light-emitting element 12 which emits light in a near-infrared region; a light-receiving element 13 which receives light in visible and near-infrared regions; a light-emitting sided-optical waveguide 14 connected to the light-emitting element 12 and having an output end; and a light-receiving sided-optical waveguide 15 connected to the light-receiving element 13 and having an input end. The output end 14a of the light-emitting sided-optical waveguide 14 and the input end 15a of the light-receiving sided-optical waveguide 15 are located on opposite sides of the coordinate input region. The light-receiving sided-optical waveguide 15 has an organic colored layer 16 provided on at least part of a surface thereof. The organic colored layer 16 has a lower light transmittance in a visible light region than in a near-infrared region.

Abstract: An electrolyte membrane (1) includes a base material layer (1) containing a hydrocarbon-based electrolyte as a main component, and a surface layer (5) laminated with the base material layer (1). The surface layer (5) is a layer containing, as a main component, a polymeric material having a hydroxyl group and a proton conductive group. The polymeric material that constitutes the surface layer (5) contains, for example, a first polymer having a hydroxyl group, and a second polymer having a proton conductive group. A matrix is formed by cross-linking the first polymer, and the second polymer can be held in the matrix.

Abstract: A method of manufacturing a proton-conductive polymer electrolyte membrane using polyvinyl alcohol (PVA) as a base material and having excellent proton conductivity and methanol blocking properties is provided. The method includes: heat-treating a precursor membrane including PVA and a water-soluble polymer electrolyte having a proton conductive group to proceed crystallization of the PVA; and chemically crosslinking the heat-treated precursor membrane with a crosslinking agent reactive with the PVA, to form a polymer electrolyte membrane in which a crosslinked PVA is a base material and protons are conducted through the electrolyte retained in the base material. The content of a water-soluble polymer except the PVA and the water-soluble polymer electrolyte in the precursor membrane is in a weight ratio of less than 0.1 with respect to the PVA.

Abstract: The present invention relates to a cell culture substrate in which a polymer chain having a hydrophilic skeleton is grafted onto a surface of polystyrene or poly(?-caprolactone) having a water contact angle of from 75° to 100°. This cell culture substrate has excellent efficiency of cell culture without the necessity of immobilization and adsorption of a cell adhesion substance on a surface of a substrate.

Abstract: An optical touch panel 10 includes: a coordinate input region 11; a light-emitting element 12 which emits light in a near-infrared region; a light-receiving element 13 which receives light in visible and near-infrared regions; a light-emitting sided-optical waveguide 14 connected to the light-emitting element 12 and having an output end; and a light-receiving sided-optical waveguide 15 connected to the light-receiving element 13 and having an input end. The output end 14a of the light-emitting sided-optical waveguide 14 and the input end 15a of the light-receiving sided-optical waveguide 15 are located on opposite sides of the coordinate input region. The light-receiving sided-optical waveguide 15 has an organic colored layer 16 provided on at least part of a surface thereof. The organic colored layer 16 has a lower light transmittance in a visible light region than in a near-infrared region.