Abstract: A method of manufacturing wavelength converting members includes: disposing masks having a rectangular shape in plan view on an upper surface of a wavelength converting substrate; singulating the substrate into workpieces, each including an upper surface and lateral surfaces, with a predetermined size and a rectangular shape in plan view such that the upper surface includes one of the masks and a portion of the substrate; aligning a predetermined number of the workpieces and disposing a light-shielding film on the lateral surfaces and the upper surface of each workpiece, and on the mask of each workpiece; removing the masks with portions of the light-shielding film on the masks, while maintaining a portion of the light-shielding film on the upper surfaces of the workpieces at portions surrounding the masks; and reducing a thickness of a portion of each workpiece where the mask has been removed.

Abstract: The light emitting device includes: at least one light emitting element including a light-extracting surface and at least one lateral surface; a wavelength converting member including; a first upper surface and a second upper surface, a lower surface located at an opposite side from the first upper surface and the second upper surface, at least one first lateral surface connecting the second upper surface and the first upper surface, and at least one second lateral surface connecting the second upper surface and the lower surface, in which a thickness between the lower surface and the first upper surface is smaller than a thickness between the lower surface and the second upper surface, and the first upper surface is located at an opposite side from the light-extracting surface of a corresponding one of the at least one light emitting element, and the lower surface is located facing the light-extracting surface of the corresponding one of the at least one light emitting element; a covering member covering the

Abstract: The light emitting device includes: at least one light emitting element including a light-extracting surface and at least one lateral surface; a wavelength converting member including; a first upper surface and a second upper surface, a lower surface located at an opposite side from the first upper surface and the second upper surface, at least one first lateral surface connecting the second upper surface and the first upper surface, and at least one second lateral surface connecting the second upper surface and the lower surface, in which a thickness between the lower surface and the first upper surface is smaller than a thickness between the lower surface and the second upper surface, and the first upper surface is located at an opposite side from the light-extracting surface of a corresponding one of the at least one light emitting element, and the lower surface is located facing the light-extracting surface of the corresponding one of the at least one light emitting element; a covering member covering the

Abstract: A light emitting device including: a light emitting element, a phosphor plate, and a light guiding part. The lower face of the light emitting element has a rectangular shape. The light guiding part covers lateral faces of the light emitting element and the lower face of the phosphor plate that is exposed from the light emitting element. The light guiding part has one or more lateral faces having at least one of structures below: a height at both ends being different from the height at a central area; outer lateral faces being parallel to the lateral faces of the light emitting element.

Abstract: A light emitting device includes a light emitting element, a light transmissive member, and a cover member. The light transmissive member is disposed on an upper face of the light emitting element. The cover member covers a lateral face of the light emitting element and a lateral face of the light transmissive member, and includes first and second cover members. The first cover member is disposed adjacent to the lateral face of the light emitting element and the lateral face of the light transmissive member, and contains a first light reflecting material and a fluorine-based first resin. The second cover member covers the first cover member, and contains a second light reflecting material and a second resin. A refractive index difference between the first light reflecting material and the first resin is larger than a refractive index difference between the second light reflecting material and the second resin.

Abstract: A light emitting device Includes a light emitting element, a light transmissive member, and a cover member. The light transmissive member is disposed on an upper face of the light emitting element. The cover member covers a lateral face of the light emitting element and a lateral face of the light transmissive member, and includes first and second cover members. The first cover member is disposed adjacent to the lateral face of the light emitting element and the lateral face of the light transmissive member, and contains a first light reflecting material and a fluorine-based first resin. The second cover member covers the first cover member, and contains a second light reflecting material and a second resin. A refractive index difference between the first light reflecting material and the first resin is larger than a refractive index difference between the second light reflecting material and the second resin.

Abstract: A light emitting device including: a light emitting element, a phosphor plate, and a light guiding part. The lower face of the light emitting element has a rectangular shape. The light guiding part covers lateral faces of the light emitting element and the lower face of the phosphor plate that is exposed from the light emitting element. The light guiding part has one or more lateral faces having at least one of structures below: a height at both ends being different from the height at a central area; outer lateral faces being parallel to the lateral faces of the light emitting element.

Abstract: A nitride group semiconductor light emitting device includes a nitride group semiconductor layer, and an electrode structure. The electrode structure is arranged on or above the semiconductor layer, and includes a plurality of deposited metal layers. The plurality of deposited metal layers of the electrode structure includes first and second metal layers. The first metal layer is arranged on the semiconductor layer side. The second metal layer is arranged on or above the first metal layer. The first metal layer contains Cr, and a first metal material. The first metal material has a reflectivity higher than Cr at the light emission peak wavelength of the light emitting device. According to this construction, the first metal layer can have a higher reflectivity as compared with the case where the first metal layer is only formed of Cr, but can keep tight contact with the semiconductor layer.

Abstract: To provide a method of manufacturing a nitride semiconductor light emitting element, which has a small number of steps and thus, can improve productivity, the method of manufacturing a nitride semiconductor light emitting element including a nitride semiconductor light emitting element structure having an n-type nitride semiconductor layer and a p-side nitride semiconductor layer which are laminated on a substrate, an n-side pad electrode connecting surface and a p-side pad electrode connecting surface which are formed on the same plane of the substrate; a n-side pad electrode on the n-side pad electrode connecting surface; and a p-side pad electrode on the p-side pad electrode connecting surface, and in the manufacturing method, a pad electrode layer forming step, a resist pattern forming step, a pad electrode layer etching step, a protective layer forming step and a resist pattern removing step are sequentially performed.

Abstract: A nitride group semiconductor light emitting device includes a nitride group semiconductor layer, and an electrode structure. The electrode structure is arranged on or above the semiconductor layer, and includes a plurality of deposited metal layers. The plurality of deposited metal layers of the electrode structure includes first and second and metal layers. The first metal layer is arranged on the semiconductor layer side. The second metal layer is arranged on or above the first metal layer. The first metal layer contains Cr, and a first metal material. The first metal material has a reflectivity higher than Cr at the light emission peak wavelength of the light emitting device. According to this construction, the first metal layer can have a higher reflectivity as compared with the case where the first metal layer is only formed of Cr, but can keep tight contact with the semiconductor layer.

Abstract: To provide a method of manufacturing a nitride semiconductor light emitting element, which has a small number of steps and thus, can improve productivity, the method of manufacturing a nitride semiconductor light emitting element including a nitride semiconductor light emitting element structure having an n-type nitride semiconductor layer and a p-side nitride semiconductor layer which are laminated on a substrate, an n-side pad electrode connecting surface and a p-side pad electrode connecting surface which are formed on the same plane of the substrate; a n-side pad electrode on the n-side pad electrode connecting surface; and a p-side pad electrode on the p-side pad electrode connecting surface, and in the manufacturing method, a pad electrode layer forming step, a resist pattern forming step, a pad electrode layer etching step, a protective layer forming step and a resist pattern removing step are sequentially performed.