Solution for use in filling micrometer-size cavities (10), the solution comprising a first solvent, a first polymer (102) having a first molecular weight, a second polymer (103) having a second molecular weight, luminophores (101) and a surfactant, the second molecular weight being 10 to 50 times greater than the first molecular weight.

An embodiment provides a phosphor composition and a light emitting device package comprising the same, wherein the phosphor composition comprises green phosphor, amber phosphor, and red phosphor, wherein the amber phosphor is expressed as chemical formula Li.sub.m−2XSi.sub.12-m−nAl.sub.m+nO.sub.nN.sub.16-n:Eu.sup.2+, where 2≦m≦5, 2≦n≦10, 0.01≦X≦1. The light emitting element package of the embodiment can display white light having improved brightness and color rendering index.

An LED light-emission device includes a substrate, an LED chip, a phosphor-containing resin containing a phosphor and covering the LED chip, and a diffusing agent-containing resin containing a diffusing agent that diffuses light emitted from the phosphor-containing resin and sealing the phosphor-containing resin. The LED chip, the phosphor-containing resin, and the diffusing agent-containing resin are placed on a same flat face of the substrate.

Embodiments of the invention include a semiconductor light emitting device for emitting a first light at a first wavelength and a wavelength conversion medium arranged to convert at least part of the first light into a second light at a second wavelength. The wavelength conversion medium is disposed between a periodic antenna array and the semiconductor light emitting device. The periodic antenna array includes a plurality of antennas. The periodic antenna array supports surface lattice resonances arising from diffractive coupling of localized surface plasmon resonances in at least one of the antennas.

A method for producing a photo-luminescent material, including the following steps: (1) producing, according to a sol-gel method, a sol and then a gel of first precursors of a first substance from the sol; (2) crushing the gel; (3) optionally, annealing the gel in order to form first particles of the first substance of which the average size is between 1 pm and 20 um; (4) producing a colloidal dispersion of second particles of a second substance, different from the first substance or identical to the first substance, of which the average size is between 5 nm and 400 nm; (5) mixing the colloidal dispersion with the sol in step (1) before forming the gel or with the first particles after step (3); and (6) annealing the mixture obtained in step (5), resulting in an increase in the compactness of the mixture, the average size of the second particles after annealing being between 100 nm and 900 nm. A photo-luminescent material including a mixture of first particles of a first photo-luminescent substance of which the average size is between 1 pm and 20 pm and second particles of a second photo-luminescent substance, different from the first photo-luminescent substance or identical to the first photo-luminescent substance, of which the average size is between 100 nm and 900 nm.

A glass material is provided, which has a composition of M.sub.2O—ZnO-M′.sub.20.sub.3—Bi.sub.2O.sub.3—SiO.sub.2, wherein M is Li, Na, K, or a combination thereof, and M′ is B, Al, or a combination thereof. A fluorescent composite material can be composed of the glass material and a phosphor material. The fluorescent composite material may collocate with an excitation light source to provide a light-emitting device.

A ceramic or polycrystalline scintillator composition is represented by the formula (Lu.sub.yGd.sub.3-y)(Ga.sub.xAl.sub.5-x)O.sub.12:Ce; wherein y=1±0.5; wherein x=3±0.25; and wherein Ce is in the range 0.01 mol % to 0.7 mol %. The scintillator composition finds application in the sensitive detection of ionizing radiation and may for example be used in the detection of gamma photons in the field of PET imaging.

A fluorescent material comprises a compound having the general formula of:

[Lu.sub.1−a−c−d−2/3bY.sub.aΣ(Ln−1).sub.cΣ(Ln−2).sub.dM.sub.b].sub.3±δ[Al.sub.1−xGa.sub.x].sub.5(O.sub.1−1/2yX.sub.y).sub.12±1.5δ.

The fluorescent material is combined with other compounds to form a photo-luminescent composition. The fluorescent material and the composition containing the same have a lot of advantages, such as high brightness, high color rendering index, high stability, and low light decay.

A white light-emitting device includes a light-emitting element that emits a blue light, and a sealing resin that seals the light-emitting element and that includes a first phosphor and a second phosphor, the first phosphor wavelength-converting a portion of the blue light and emitting a red light, the second phosphor wavelength-converting a portion of the blue light and emitting a green light. The white light-emitting device emits a white light by mixing the blue, red and green lights. The sealing resin further includes a third phosphor that wavelength-converts a portion of the blue light, emits a light in a same color gamut as the first or second phosphor, and has a higher light conversion efficiency than the first or second phosphor. The third phosphor is included in the sealing resin at an additive amount less than an amount that causes a change in a spectrum of the white light.

A light-emitting ceramic and a light-emitting device. The light-emitting ceramic comprises a YAG substrate and light-emitting centers and diffusion particles evenly dispersed in the YAG substrate. The light-emitting centers are lanthanide-doped YAG fluorescent powder particles of 10-20 μm in grain size. The particle size of the scattering particles is 20-50 nm. The YAG substrate is a lanthanide-doped YAG ceramic. Also, the grain size of the YAG substrate is less than the grain size of the YAG fluorescent powder particles.