A light emitting device includes a flexible substrate, at least one light emitting element, a sealing resin, an adhesion layer and a support member. The flexible substrate includes a flexible base member and a plurality of wiring portions disposed on one surface of the base member. At least one light emitting element is arranged on a first surface of the flexible substrate and electrically connected to the wiring portions. The sealing resin seals the at least one light emitting element. The adhesion layer and the support member are arranged in this order on a second surface of the flexible substrate different from the first surface of the flexible substrate. The support member has a recess in a region corresponding at least to a region on the first surface where the at least one light emitting element is arranged.

An optoelectronic semiconductor device comprises a barrier layer, a first semiconductor layer on the barrier layer, the first semiconductor layer comprising a first dopant and a second dopant, and a second semiconductor layer beneath the barrier layer, the second semiconductor comprising the second dopant, wherein, in the first semiconductor layer, a concentration of the first dopant is larger than a concentration of the second dopant, and the concentration of the second dopant in the second semiconductor layer is larger than that in the first semiconductor layer.

An optoelectronic semiconductor device comprises a barrier layer, a first semiconductor layer on the barrier layer, the first semiconductor layer comprising a first dopant and a second dopant, and a second semiconductor layer beneath the barrier layer, the second semiconductor comprising the second dopant, wherein, in the first semiconductor layer, a concentration of the first dopant is larger than a concentration of the second dopant, and the concentration of the second dopant in the second semiconductor layer is larger than that in the first semiconductor layer.

A method for homogenizing the height of a plurality of wires from the plurality of wires erected on a face of a substrate, the method including a first step of coating the face of the substrate including the plurality of wires with a first film, the first film embedding the plurality of wires over a first height; a second step of coating the first film with a second film, the second film embedding at least one part of the plurality of wires over a second height; a step of removing the second film, the part of the wires of the plurality of wires embedded in the second film being removed at the same time as the second film, a mechanical stress between the first film and the second film being exerted during the removal step.

A method for homogenizing the height of a plurality of wires from the plurality of wires erected on a face of a substrate, the method including a first step of coating the face of the substrate including the plurality of wires with a first film, the first film embedding the plurality of wires over a first height; a second step of coating the first film with a second film, the second film embedding at least one part of the plurality of wires over a second height; a step of removing the second film, the part of the wires of the plurality of wires embedded in the second film being removed at the same time as the second film, a mechanical stress between the first film and the second film being exerted during the removal step.

A semiconductor light source that includes a substrate B and a plurality of semiconductor light-emitting rods extending respectively from the substrate, and a plurality of separating walls also extending from the substrate. The separating walls are arranged between the rods in such a way as to define groups of rods, and such that at least two separating walls have a different height.

A light-emitting device comprises a carrier; a first semiconductor element formed on the carrier and comprising a first semiconductor structure and a second semiconductor structure, wherein the second semiconductor structure is closer to the carrier than the first semiconductor structure is, the first semiconductor structure comprises a first active layer emitting a first light having a first dominant wavelength during a normal operation, and the second semiconductor structure comprises a second active layer; and a bridge on a side surface of the second active layer of the second semiconductor structure.

A light-emitting diode (LED) and a backlight-type display device are provided. The light-emitting diode includes: a multi-color light emitting chip, an emission spectrum thereof including a first peak in a wavelength range of a first primary-color light and a second peak in a wavelength range of a second primary-color light, and an absolute value of a wavelength difference between the first and second peaks being greater than 50 nm; and a phosphor-containing layer, disposed over the multi-color light emitting chip and used to be excited to emit a third primary-color light. Owing to the LED adopts the multi-color light emitting chip which has the first and second peaks in different wavelength ranges and the absolute valve of the wavelength difference is greater than 50 nm, RGB three-primary-color lights can be outputted by adopting a single-color light phosphor powder with relatively high reliability. The backlight-type display device can obtain a high NTSC level.

The present invention relates to an electrode assembly comprising nano-scale-LED elements and a method for manufacturing the same and, more specifically, to an electrode assembly comprising nano-scale-LED elements and a method for manufacturing the same, in which the number of nano-scale-LED elements included in a unit area of the electrode assembly is increased, the light extraction efficiency of individual nano-scale-LED elements is increased so as to maximize light intensity per unit area, and at the same time, nano-scale-LED elements on a nanoscale are connected to an electrode without a fault such as an electrical short circuit.

The present invention relates to an electrode assembly comprising nano-scale-LED elements and a method for manufacturing the same and, more specifically, to an electrode assembly comprising nano-scale-LED elements and a method for manufacturing the same, in which the number of nano-scale-LED elements included in a unit area of the electrode assembly is increased, the light extraction efficiency of individual nano-scale-LED elements is increased so as to maximize light intensity per unit area, and at the same time, nano-scale-LED elements on a nanoscale are connected to an electrode without a fault such as an electrical short circuit.