An emitting device comprising a first light emitter adapted to emit a first radiation, and a second light emitter adapted to emit a second radiation different from the first radiation, the first light emitter comprising a first semiconducting structure and a first radiation converter, the second light emitter comprising a second semiconducting structure and a second radiation converter, each semiconducting structure comprising a semiconducting layer adapted to emit a third radiation, each radiation converter comprising a set of particles able to convert the third radiation into the first or second radiation, the particles of the first radiation converter being attached to a surface by a bulk of photosensitive resin and the particles of the second radiation converter being attached to a surface by grafting.

Embodiments disclosed herein include micro light emitting device (LED) display panels and methods of forming such devices. In an embodiment, a display panel includes a display backplane substrate, a light emitting element on the display backplane, a transparent conductor over the light emitting element, a dielectric layer over the transparent conductor, and a color conversion device over the light emitting element. In an embodiment, the dielectric layer separates the transparent conductor from the color conversion device.

A method includes: bonding a surface of a first wafer on a side having a semiconductor layer to a surface of a second wafer on a side having a first electrode to electrically connect the semiconductor layer and the first electrode; etching a silicon substrate such that a first portion of the silicon substrate remains in a region overlapping with the first electrode in a plan view; etching the semiconductor layer using the first portion as a mask such that a portion of the semiconductor layer between the first portion and the first electrode remains as at least one light-emitting portion; forming a resin layer to cover a lateral surface of the first portion and a lateral surface of the light-emitting portion with the resin layer; removing the first portion to expose the light-emitting portion; and forming a light-transmissive electrically conductive film on or above the light-emitting portion.

An electronic device includes a plurality of light emitting units mounted on a substrate, and an opening that is provided so as to correspond to each of the light emitting units and guides light emitted from the light emitting units to an outside.

The present disclosure provides a display panel and a display device. The display panel includes: a base substrate; a plurality of micro-LED groups located on the base substrate, wherein each of the plurality of micro-LED groups includes at least three micro-LEDs, and at least two micro-LEDs of each said micro-LED group have their longer sides arranged in different directions; and a shielding layer comprising a plurality of apertures located in shielding portions, wherein the shielding portions are located between adjacent micro-LEDs, and wherein the plurality of apertures each correlates one of the micro-LEDs.

A chip transfer assembly and a manufacturing method therefor, a chip transfer method, and a display backplane. The chip transfer assembly comprises a transfer substrate (1); a porous adhesive layer (2) formed on the transfer substrate, first pores (21) being distributed in the porous adhesive layer; and at least one colloid protrusions (3) formed on the porous adhesive layer, the colloid protrusions having light transmittance, and second pores (31) used for accommodating luminescent conversion particles (4) being distributed in the colloid protrusions; after an LED chip (7) is transferred to a chip soldering zone, the colloid protrusions separate from the porous adhesive layer and remain on the LED chip to form a luminescent conversion layer.

Alight emitting device includes: a light emitting element; a first substrate having an upper surface comprising an element placement region on which the light emitting element is disposed; a light-transmissive member with a sheet-like shape that covers the light emitting element, wherein an outer edge of a lower surface of the light-transmissive member contacts an outer side of the upper surface of the element placement region of the first substrate; and a first protrusion portion disposed along an outer edge of an upper surface of the light-transmissive member and extending across an upper surface of the first substrate and the upper surface of the light-transmissive member, wherein the first protrusion portion comprises a top portion located higher than an upper surface of the light emitting element.

A display device includes a first substrate, a light-emitting element, a light conversion layer, and a color filter layer. The light-emitting element is disposed on the first substrate. The light conversion layer is disposed on the light-emitting element. In addition, the color filter layer is overlapped the light-emitting element and the light conversion layer.

A light-emitting device includes a base including a conductive wiring; a light-emitting element mounted on the base and configured to emit light; a light reflective film provided on an upper surface of the light-emitting element; and a encapsulant covering the light-emitting element and the light reflective film. A ratio (H/W) of a height (H) of the encapsulant to a width (W) of a bottom surface of the encapsulant is less than 0.5.

The invention relates to a method for producing a conversion element for an optoelectronic component comprising the steps of: A) Producing a first layer, for that purpose: A1) Providing a polysiloxane precursor material, which is liquid, A2) Mixing a phosphor to the polysiloxane precursor material, wherein the phosphor is suitable for conversion of radiation, A3) Curing the arrangement produced under step A2) to produce a first layer having a phosphor mixed in a cured polysiloxane material, which comprises a three-dimensional crosslinking network based primarily on T-units, where the ratio of T-units to all units is greater than 80%, B) Producing a phosphor-free second layer, for that purpose: B1) Providing the polysiloxane precursor material, which is liquid, B2) Mixing a filler to the polysiloxane precursor material, wherein the filler is in a cured and powdered form, wherein the filler has a refractive index, which is equal to the refractive index of the cured polysiloxane material, B3) Curing the arrangement produced under step B2) to produce a second layer having a filler mixed in the cured polysiloxane material, which comprises a three-dimensional crosslinking network based primarily on T-units, wherein the produced conversion element is formed as a plate having a thickness of at least 100 μm.