A method of fabricating a light-emitting device including the steps of forming a first resin including a phosphor on a light-emitting diode chip mounted on a package body, measuring color coordinates of light emitted by combination of the light-emitting diode chip and the phosphor, correcting the color coordinates by forming a second resin on the first resin, and curing the first resin and the second resin after correcting the color coordinates, in which the first resin is not fully cured before measuring and correcting the color coordinates.

A package method includes steps of providing a light emitting module, a mold and a molding compound, wherein the light emitting module includes a substrate and at least one light emitting unit disposed on the substrate, the mold has at least one recess, and a side wall of the recess is parallel to a side surface of the light emitting unit; filling the recess with the molding compound; placing the substrate on the mold reversely, so that the light emitting unit is immersed into the recess and the molding compound directly encapsulates the light emitting unit; and heating and pressing the substrate and the mold, so as to solidify the molding compound.

A method for manufacturing a light emitting device includes preparing a light emitting element that includes a light transmissive substrate comprising a first main surface, a second main surface, and a side surface having a light transmitting part and a light absorbing part whose optical transmissivity is lower than that of the light transmitting part, and a semiconductor laminate that is provided to the first main surface of the light transmissive substrate, joining the light emitting element to an upper surface of a base body such that the base body is opposite to the side where the semiconductor laminate is provided, providing a support member that covers the side surface of the light emitting element and part of the base body, and removing the light absorbing part by thinning the light transmissive substrate from the second main surface side.

A lead frame for mounting LED elements includes a frame body region and a large number of package regions arranged in multiple rows and columns in the frame body region. The package regions each include a die pad on which an LED element is to be mounted and a lead section adjacent to the die pad, the package regions being further constructed to be interconnected via a dicing region. The die pad in one package region and the lead section in another package region upward or downward adjacent to the package region of interest are connected to each other by an inclined reinforcement piece positioned in the dicing region.

Various methods and apparatuses are disclosed. A method may include disposing at least one die on a location on a carrier substrate, forming at least one stud bump on each of at least one die, forming a phosphor layer on the at least one stud bump and the at least one die, removing a top portion of the phosphor layer to expose the at least one stud bump, and removing a side portion of the phosphor layer located between two adjacent dies. An apparatus may include a die comprising top, bottom, and side surfaces. A phosphor layer may be disposed on the top, bottom, and side surfaces of the die. The phosphor layer may have substantially equal thicknesses on the top and side surfaces of the die as well as one or more stud bumps disposed on the top surface of the die.

An optoelectronic component includes at least one inorganic optoelectronically active semiconductor component having an active region that emits or receives light during operation, and a sealing material directly applied by atomic layer deposition, wherein the semiconductor component is applied on a carrier, the carrier includes electrical connection layers, the semiconductor component electrically connects to one of the electrical connection layers via an electrical contact element, and the sealing material completely covers in a hermetically impermeable manner and directly contacts all exposed surfaces including sidewall and bottom surfaces of the semiconductor component and the electrical contact element and all exposed surfaces of the carrier apart from an electrical connection region of the carrier.

A method for producing a light emitting device includes a first bonding step including disposing a first bonding member a mounting substrate, placing a light emitting element on the mounting substrate such that the first bonding member is located between a mounting face of the light emitting element and the mounting substrate, and hardening the first bonding member thereby bonding the light emitting element and the mounting substrate such that, in a plan view, an entirety of the first bonding member is contained within an area of the mounting face of the light emitting element; and a second bonding step including disposing a second bonding member on the upper face of the mounting substrate such that, in a plan view, the second bonding member is located at at least a portion of an outer edge of the mounting face of the light emitting element, and hardening the second bonding member.

The present application relates to a light-emitting film, a method of manufacturing the same, a lighting device and a display device. The present application may provide a light-emitting film capable of providing a lighting device having excellent color purity and efficiency and an excellent color characteristic. The characteristics of the light-emitting film of the present application may be stably and excellently maintained for a long time. The light-emitting film of the present application may be used for various uses including photovoltaic applications, an optical filter or an optical converter, as well as various lighting devices.

A method for manufacturing a light-emitting device includes providing a soluble member to cover at least one lateral surface of a light-emitting element. The soluble member includes a material soluble in a first solvent. A light-shielding member is provided to cover at least one lateral surface of the soluble member. The light-shielding member includes a light-shielding resin less soluble in the first solvent than the soluble member. The soluble member is removed with the first solvent. A first light-transmissive member is provided in a space formed by removing the soluble member.

A light emitting device includes: a light emitting element that includes a light extracting surface, an electrode formed surface opposite to the light extracting surface, one or more lateral surfaces, and a pair of electrodes positioned on the electrode formed surface; a light-transmissive member that includes a light entering surface, a light exiting surface opposite to the light entering surface, and one or more lateral surfaces, the light entering surface being disposed on the light extracting surface; an insulating member that covers the lateral surfaces and the electrode formed surface of the light emitting element, and is disposed to expose at least part of the pair of electrodes; a first metal layer that covers the lateral surfaces of the light-transmissive member; and a second metal layer that covers the lateral surfaces of the light emitting element interposing the insulating member.