Organic light emitting diode, method for manufacturing same, image display device, and illuminating device

The invention claimed is: 1. An organic light emitting diode selected from the group consisting of: (a) an organic light emitting diode in which at least an anodic conductive layer formed from a transparent conductor, an organic electroluminescence layer that includes a light emitting layer containing an organic light emitting material, and a cathodic conductive layer formed from Al or an alloy containing 70% by mass or more of Al are sequentially laminated on a transparent substrate, and a lattice structure, in which a plurality of concave portions are periodically and two-dimensionally arranged, wherein the concave portions are provided to the cathodic conductive layer at an interface between the cathodic conductive layer and the organic electroluminescence layer, wherein the lattice structure is a triangular lattice structure; wherein an extraction wavelength λ (nm) of light from the organic light emitting diode and a distance p (nm) between centers of the concave portions in the lattice structure are within a polygonal-shaped region defined by straight lines sequentially connecting the following coordinates A′, B′, C′, D′, E′, F′, G′, H′, I′, J′, K′, L′, and A′ in a graph illustrating a relationship between the light extraction wavelength and the distance p (nm) between centers of the concave portions in the lattice structure, wherein A′ (λ=300, p=220), B′ (λ=400, p=295), C′ (λ=500, p=368), D′ (λ=600, p=438), E′ (λ=700, p=508), F′ (λ=800, p=575), G′ (λ=800, p=505), H′ (λ=700, p=438), I′ (λ=600, p=368), J′ (λ=500, p=298), K′ (λ=400, p=225), and L′ (λ=300, p=150); and a depth of the concave portions is 12 nm to 180 nm, wherein the relationship between the extraction wavelength and distance between adjacent centers of the concave portions in the lattice structure and a depth of corresponding concave portions in the lattice structure combine to enhance luminous efficiency; (b) an organic light emitting diode in which at least a cathodic conductive layer formed from Al or an alloy containing 70% by mass or more of Al, an organic electroluminescence layer that includes a light emitting layer containing an organic light emitting material, and an anodic conductive layer formed from a transparent conductor are sequentially laminated on a substrate, and a lattice structure, in which a plurality of concave portions are periodically and two-dimensionally arranged, wherein the concave portions are provided to the cathodic conductive layer at an interface between the cathodic conductive layer and the organic electroluminescence layer, wherein the lattice structure is a triangular lattice structure; wherein an extraction wavelength λ (nm) of light from the organic light emitting diode and a distance p (nm) between centers of the concave portions in the lattice structure are within a polygonal-shaped region defined by straight lines sequentially connecting the following coordinates A′, B′, C′, D′, E′, F′, G′, H′, I′, J′, K′, L′, and A′ in a graph illustrating a relationship between the light extraction wavelength and the distance p (nm) between centers of the concave portions in the lattice structure, wherein A′ (λ=300, p=220), B′ (λ=400, p=295), C′ (λ=500, p=368), D′ (λ=600, p=438), E′ (λ=700, p=508), F′ (λ=800, p=575), G′ (λ=800, p=505), H′ (λ=700, p=438), I′ (λ=600, p=368), J′ (λ=500, p=298), K′ (λ=400, p=225), and L′ (λ=300, p=150); and a depth of the concave portions is 12 nm to 180 nm, wherein the relationship between the extraction wavelength and distance between adjacent centers of the concave portions in the lattice structure and a depth of corresponding concave portions in the lattice structure combine to enhance luminous efficiency; (c) an organic light emitting diode in which at least an anodic conductive layer formed from a transparent conductor, an organic electroluminescence layer that includes a light emitting layer containing an organic light emitting material, and a cathodic conductive layer formed from Al or an alloy containing 70% by mass or more of Al are sequentially laminated on a transparent substrate, and a lattice structure, in which a plurality of convex portions are periodically and two-dimensionally arranged, wherein the convex portions are provided to the cathodic conductive layer at an interface between the cathodic conductive layer and the organic electroluminescence layer, wherein the lattice structure is a triangular lattice structure; wherein an extraction wavelength λ (nm) of light from the organic light emitting diode and a distance p (nm) between centers of the convex portions in the lattice structure are within a polygonal-shaped region defined by straight lines sequentially connecting the following coordinates A′, B′, C′, D′, E′, F′, G′, H′, I′, J′, K′, L′, and A′ in a graph illustrating a relationship between the light extraction wavelength and the distance p (nm) between centers of the convex portions in the lattice structure, wherein A′ (λ=300, p=220), B′ (λ=400, p=295), C′ (λ=500, p=368), D′ (λ=600, p=438), E′ (λ=700, p=508), F′ (λ=800, p=575), G′ (λ=800, p=505), H′ (λ=700, p=438), I′ (λ=600, p=368), J′ (λ=500, p=298), K′ (λ=400, p=225), and L′ (λ=300, p=150); and a height of the convex portions is 12 nm to 180 nm, wherein the relationship between the extraction wavelength and distance between adjacent centers of the convex portions in the lattice structure and a height of corresponding convex portions in the lattice structure combine to enhance luminous efficiency; (d) an organic light emitting diode in which at least a cathodic conductive layer formed from Al or an alloy containing 70% by mass or more of Al, an organic electroluminescence layer that includes a light emitting layer containing an organic light emitting material, and an anodic conductive layer formed from a transparent conductor are sequentially laminated on a substrate, and a lattice structure, in which a plurality of convex portions are periodically and two-dimensionally arranged, wherein the convex portions are provided to the cathodic conductive layer at an interface between the cathodic conductive layer and the organic electroluminescence layer, wherein the lattice structure is a triangular lattice structure; wherein an extraction wavelength λ (nm) of light from the organic light emitting diode and a distance p (nm) between centers of the convex portions in the lattice structure are within a polygonal-shaped region defined by straight lines sequentially connecting the following coordinates A′, B′, C′, D′, E′, F′, G′, H′, I′, J′, K′, L′, and A′ in a graph illustrating a relationship between the light extraction wavelength and the distance p (nm) between centers of the convex portions in the lattice structure, wherein A′ (λ=300, p=220), B′ (λ=400, p=295), C′ (λ=500, p=368), D′ (λ=600, p=438), E′ (λ=700, p=508), F′ (λ=800, p=575), G′ (λ=800, p=505), H′ (λ=700, p=438), I′ (λ=600, p=368), J′ (λ=500, p=298), K′ (λ=400, p=225), and L′ (λ=300, p=150); and a height of the convex portions is 12 nm to 180 nm, wherein the relationship between the extraction wavelength and distance between adjacent centers of the convex portions in the lattice structure and a height of corresponding convex portions in the lattice structure combine to enhance luminous efficiency. 2. The organic light emitting diode according to claim 1 , wherein the organic light emitting diode is selected from the group consisting of (a) and (b), and a depth of the concave portions is 15 nm to 70 nm. 3. The organic light emitting diode according to claim 2 , wherein a shape of the concave portions is the shape obtained by transfer of a truncated conical shape or a columnar shape on the substrate. 4. The organic light emitting diode according to claim 1 , wherein the organic light emitting diode is selected from the group consisting of (a) and (b), a shape of the conc