Abstract: A coater (1) includes: a droplet jet part (4) which ejects droplets of a first solution toward an object to be coated (2) to apply the droplets to the object to be coated (2); and a remoisturizing-drying part (6) which gives a residue of the first solution applied on the object to be coated (2) a solvent capable of dissolving the residue to form an applied body with a second solution containing the residue as a solute, and which dries the formed applied body with the second solution.

Abstract: A photocatalyst dispersion element includes: a photocatalytic material; a solvent; and an ion additive. The ion additive generates a cation having a smaller ion radius than a tetramethylammonium ion in the solvent.

Abstract: A nozzle plate includes: a first silicon layer; a glass layer; a second silicon layer provided between the first silicon layer and the glass layer, the second silicon layer being bonded to the glass layer; and a silicon oxide layer provided between the first silicon layer and the second silicon layer. A nozzle hole passing through the first silicon layer and discharging a droplet is formed. A channel passing through the silicon oxide layer and the second silicon layer and communicating with the nozzle hole is formed. A liquid chamber formed in the glass layer and communicating with the channel is formed.

Abstract: In a fluorescer solution, a plurality of types of fluorescent particles are contained in a resin liquid. Average particle sizes of these fluorescent particles decrease as densities of the types increase. In other words, average settling rates vs of the types of the fluorescent particles ascertained by v s = D p 2 × ( ? p - ? f ) × g 18 × ? are equal to each other, where Dp is an average particle size of each of the types of fluorescent particles, pp is a density of each of the types of fluorescent particles, pf is a density of the resin liquid, ? is a viscosity of the resin liquid, g is the acceleration due to gravity, and vs is an average settling rate of each of the types of fluorescent particles.

Abstract: According to one embodiment, a light emitting device includes a package member, a light emitting element provided in the package member, a first phosphor layer and a second phosphor layer. A first phosphor layer is provided on the light emitting element and has a first phosphor. A second phosphor layer is provided on the first phosphor layer and has a second phosphor. A luminescent efficiency of the first phosphor is higher than a luminescent efficiency of the second phosphor.

Abstract: A photocatalyst dispersion element includes: a photocatalytic material; a solvent; and an ion additive. The ion additive generates a cation having a smaller ion radius than a tetramethylammonium ion in the solvent.

Abstract: A photocatalyst dispersing element includes: a photocatalyst material; and a solvent. A hydrogen-ion exponent of the solvent is in a range of pH 2.1 or more and pH 5.7 or less. A method for manufacturing a photocatalyst dispersing element includes: adjusting a hydrogen-ion exponent in a solvent to be in a range of inhibiting aggregation of a photocatalyst material and of suppressing lowering of a degree of catalytic activity of the photocatalyst material; and mixing the photocatalyst material with the solvent.

Abstract: A coater (1) includes: a droplet jet part (4) which ejects droplets of a first solution toward an object to be coated (2) to apply the droplets to the object to be coated (2); and a remoisturizing-drying part (6) which gives a residue of the first solution applied on the object to be coated (2) a solvent capable of dissolving the residue to form an applied body with a second solution containing the residue as a solute, and which dries the formed applied body with the second solution.

Abstract: In a fluorescer solution, a plurality of types of fluorescent particles are contained in a resin liquid. Average particle sizes of these fluorescent particles decrease as densities of the types increase. In other words, average settling rates vs of the types of the fluorescent particles ascertained by v s = D p 2 × ( ? p - ? f ) × g 18 × ? are equal to each other, where Dp is an average particle size of each of the types of fluorescent particles, pp is a density of each of the types of fluorescent particles, pf is a density of the resin liquid, ? is a viscosity of the resin liquid, g is the acceleration due to gravity, and vs is an average settling rate of each of the types of fluorescent particles.

Abstract: A weakly alkali cleaning liquid suitable for use in the case of cleaning and removing inks adhered to a nozzle plate, in an ink jet printer using inks in which inorganic pigments and metal oxides are mixed into polymers, is provided. In the cleaning liquid, carbonates are added to the weakly alkali solution of pH 8 to pH 12.

Abstract: A photocatalyst dispersing element includes: a photocatalyst material; and a solvent. A hydrogen-ion exponent of the solvent is in a range of pH 2.1 or more and pH 5.7 or less. A method for manufacturing a photocatalyst dispersing element includes: adjusting a hydrogen-ion exponent in a solvent to be in a range of inhibiting aggregation of a photocatalyst material and of suppressing lowering of a degree of catalytic activity of the photocatalyst material; and mixing the photocatalyst material with the solvent.

Abstract: A nozzle plate includes: a first silicon layer; a glass layer; a second silicon layer provided between the first silicon layer and the glass layer, the second silicon layer being bonded to the glass layer; and a silicon oxide layer provided between the first silicon layer and the second silicon layer. A nozzle hole passing through the first silicon layer and discharging a droplet is formed. A channel passing through the silicon oxide layer and the second silicon layer and communicating with the nozzle hole is formed. A liquid chamber formed in the glass layer and communicating with the channel is formed.

Abstract: A weakly alkali cleaning liquid suitable for use in the case of cleaning and removing inks adhered to a nozzle plate, in an ink jet printer using inks in which inorganic pigments and metal oxides are mixed into polymers, is provided. In the cleaning liquid, carbonates are added to the weakly alkali solution of pH 8 to pH 12.

Abstract: According to an embodiment of the present invention, a plating apparatus, including: a plating solution tank configured to store a plating solution; a holder configured to hold a substrate on which a seed layer is formed in said plating solution tank; a first anode disposed in said plating solution tank, composed of a more anodic material in its oxidation-reduction potential than the oxidation-reduction potential of a metal composing the seed layer, and electrically connectable to the seed layer of the substrate held by said holder; and a second anode disposed in said plating solution tank, capable of applying a voltage between the seed layer of the substrate held by holder, is provided.