The present disclosure provides RGB-LED packaging modules and a display screen including a substrate; a plurality of light-emitting units disposed on the substrate, each light-emitting unit including a set of RGB-LED chips; a plastic layer provided on the light-emitting units; and a virtual isolating region provided between the light-emitting units, the virtual isolating region including a black light-absorbing layer provided on the substrate. The present disclosure makes use of the black light-absorbing layer to absorb light which may cause interference among the light-emitting units. By providing the virtual isolating region and an isolating trough, and utilizing the difference of refractive index of packaging plastic and refractive index of air, light emitted by the light-emitting units can be reflected to reduce the influence of adjacent light-emitting units. A black isolating-frame is filled in the isolating trough to minimize the interference among the light-emitting units.

A method of bonding a light-emitting diode (LED) with a substrate includes providing a LED disposed on a bottom surface of a LED substrate; forming a first isolating layer entirely on a substrate; forming a second isolating layer on the first isolating layer within a first area corresponding to an N-type contact pad of the LED; forming a first conductive layer on the second isolating layer within the first area; forming a second conductive layer on the first isolating layer within a second area corresponding to a P-type contact pad of the LED; and bonding the LED to the substrate by connecting the N-type contact pad to the first conductive layer within the first area, and connecting the P-type contact pad to the second conductive layer within the second area.

A light emitting device package according to an embodiment includes: a package body; a light emitting device disposed on the package body; and an adhesive disposed between the package body and the light emitting device. The package body includes first and second openings passing through the package body on an upper surface of the package body and a recess provided to concave in a direction of a lower surface of the package body from the upper surface of the package body. The light emitting device includes a first bonding part disposed on the first opening and a second bonding part disposed on the second opening. The adhesive is provided at the recess.

Light emitting device and methods for forming the devices include a substrate and a nanowire placed on the substrate, where the nanowire comprises a core made of a semiconductor material. A cladding encloses the nanowire and has a breakdown voltage larger than a breakdown voltage of the core. A source of an electric field is provided, where the core is at least partially aligned with and lies at least partially within the electric field such that a cycling of the electric field creates charge separation and electron-hole recombination in the core.

Light emitting device and methods for forming the devices include a substrate and a nanowire placed on the substrate, where the nanowire comprises a core made of a semiconductor material. A cladding encloses the nanowire and has a breakdown voltage larger than a breakdown voltage of the core. A source of an electric field is provided, where the core is at least partially aligned with and lies at least partially within the electric field such that a cycling of the electric field creates charge separation and electron-hole recombination in the core.

An asymmetrically shaped chip-scale packaging (CSP) light-emitting device (LED) includes an LED chip, a photoluminescent structure (or a light-transmitting structure), and a reflective structure. The photoluminescent structure covers the upper surface and/or the edge surface of the LED chip; and the reflective structure at least partially covers the edge surface of the photoluminescent structure. The reflective structure partially reflects the primary light emitted from the edge surface of the LED chip or the converted secondary light radiated from the edge surface of the photoluminescent structure, therefore shaping the radiation pattern asymmetrically.

An asymmetrically shaped chip-scale packaging (CSP) light-emitting device (LED) includes an LED chip, a photoluminescent structure (or a light-transmitting structure), and a reflective structure. The photoluminescent structure covers the upper surface and/or the edge surface of the LED chip; and the reflective structure at least partially covers the edge surface of the photoluminescent structure. The reflective structure partially reflects the primary light emitted from the edge surface of the LED chip or the converted secondary light radiated from the edge surface of the photoluminescent structure, therefore shaping the radiation pattern asymmetrically.

A light emitting diode including a side reflection layer. The light emitting diode includes: a semiconductor stack and a light exit surface having a roughened surface through which light generated from an active layer is emitted; side surfaces defining the light exit surface; and a side reflection layer covering at least part of the side surfaces. The light exit surface is disposed over a first conductivity type semiconductor layer opposite to the ohmic reflection layer, all layers from the active layer to the light exit surface are formed of gallium nitride-based semiconductors, and a distance from the active layer to the light exit surface is 50 m or more.

A Micro LED transferring method, a Micro LED display panel and a Micro LED display device are provided. The Micro LED display panel includes a substrate, a pixel defining layer including multiple openings, first conducting layer located in the multiple openings, photosensitive conductive bonding layers and Micro LED structures. The photosensitive conductive bonding layer is solidified after receiving light, such that elements adhered on two opposite surfaces of the photosensitive conductive bonding layer are bonded together. Due to the photosensitive conductive bonding layer, a Micro LED is detected during a transferring process rather than after a bonding process, thereby eliminating a step of removing a bonded abnormal Micro LED, thus simplifying the detecting and repairing processes of Micro LEDs.

A Micro LED transferring method, a Micro LED display panel and a Micro LED display device are provided. The Micro LED display panel includes a substrate, a pixel defining layer including multiple openings, first conducting layer located in the multiple openings, photosensitive conductive bonding layers and Micro LED structures. The photosensitive conductive bonding layer is solidified after receiving light, such that elements adhered on two opposite surfaces of the photosensitive conductive bonding layer are bonded together. Due to the photosensitive conductive bonding layer, a Micro LED is detected during a transferring process rather than after a bonding process, thereby eliminating a step of removing a bonded abnormal Micro LED, thus simplifying the detecting and repairing processes of Micro LEDs.