A light emitting apparatus includes: a circuit board; a plurality of light emitting devices connected to the circuit board; and a reflective sheet that reflects light emitted from the plurality of light emitting devices and includes a plurality of reflective cells which respectively accommodate the plurality of light emitting devices. The plurality of reflective cells include a plurality of low-reflection patterns. The plurality of low-reflection patterns include a pattern disposed closer to an edge of the reflective sheet, size of which is relatively smaller than size of other patterns.

A display device and a method for manufacturing the same are provided. A light-emitting element includes semiconductor layers including a first semiconductor layer, an active layer, a second semiconductor layer, and a third semiconductor layer, and defining at least one concave groove that is concave downwardly from one surface of the first semiconductor layer, a first protective layer on side surfaces of the semiconductor layers, on a top surface of the first semiconductor layer, and on inner surfaces of the semiconductor layers and on the third semiconductor layer in the concave groove, and a wavelength conversion layer containing wavelength conversion particles in the concave groove.

A display device and a method for manufacturing the same are provided. A light-emitting element includes semiconductor layers including a first semiconductor layer, an active layer, a second semiconductor layer, and a third semiconductor layer, and defining at least one concave groove that is concave downwardly from one surface of the first semiconductor layer, a first protective layer on side surfaces of the semiconductor layers, on a top surface of the first semiconductor layer, and on inner surfaces of the semiconductor layers and on the third semiconductor layer in the concave groove, and a wavelength conversion layer containing wavelength conversion particles in the concave groove.

A micro LED display panel includes a micro LED array including a plurality of micro LEDs and a plurality of electrical connection structures disposed around the plurality of micro LEDs and electrically connected to the plurality of micro LEDs. A plurality of light propagation channels are formed between adjacent ones of the micro LEDs. Each light propagation channel includes at least one of a plurality of gaps defined between adjacent ones of the electrical connection structures. From a top view of the micro LED array, the light propagation channels are flexural.

A micro LED display panel includes a micro LED array including a plurality of micro LEDs and a plurality of electrical connection structures disposed around the plurality of micro LEDs and electrically connected to the plurality of micro LEDs. A plurality of light propagation channels are formed between adjacent ones of the micro LEDs. Each light propagation channel includes at least one of a plurality of gaps defined between adjacent ones of the electrical connection structures. From a top view of the micro LED array, the light propagation channels are flexural.

This application relates to display panels and electronic devices. An example display panel includes a display area, and the display area includes a driver substrate, a pixel structure, a first reflection layer, a first reflection grating, and a second reflection layer. The driver substrate, the first reflection layer, and the pixel structure are sequentially disposed. The driver substrate is configured to enable the pixel structure to emit light, and the second reflection layer is connected to a side surface of the pixel structure. The first reflection grating and the first reflection layer form a resonant cavity, and the resonant cavity is configured to enable light with a specific wavelength emitted by the pixel structure to resonate.

This application relates to display panels and electronic devices. An example display panel includes a display area, and the display area includes a driver substrate, a pixel structure, a first reflection layer, a first reflection grating, and a second reflection layer. The driver substrate, the first reflection layer, and the pixel structure are sequentially disposed. The driver substrate is configured to enable the pixel structure to emit light, and the second reflection layer is connected to a side surface of the pixel structure. The first reflection grating and the first reflection layer form a resonant cavity, and the resonant cavity is configured to enable light with a specific wavelength emitted by the pixel structure to resonate.

The present disclosure provides a display panel and a display module, where the display panel includes a display area and a virtual terminal area; a plurality of sub-pixels of the display panel are located within the display area, and each of the sub-pixels includes at least first transistor; a light-sensing sensor is located within the virtual terminal area, and a portion of the film layer of the light-sensing sensor is disposed at the same layer as a portion of the film layer of the first transistor, so as to solve the technical problem that the existing externally-mounted light-sensing sensor is unfavorable to improvement of the screen-to-body ratios of the displays.

The present disclosure provides a display panel and a display module, where the display panel includes a display area and a virtual terminal area; a plurality of sub-pixels of the display panel are located within the display area, and each of the sub-pixels includes at least first transistor; a light-sensing sensor is located within the virtual terminal area, and a portion of the film layer of the light-sensing sensor is disposed at the same layer as a portion of the film layer of the first transistor, so as to solve the technical problem that the existing externally-mounted light-sensing sensor is unfavorable to improvement of the screen-to-body ratios of the displays.

A display includes a first housing portion having graphic openings and a second housing portion spaced apart from the first housing portion. A first circuit board has LEDs and is disposed between the first and second housing portions. A first side wall and a second side wall define photon recycling cavities in a sequence wherein adjacent photon recycling cavities have a shared end wall an LED. The first side wall has a first angular surface and the second side wall has a second angular surface. The first angular surface and the second angular surface redirecting light from an associated LED of the plurality of LEDs so that light from the plurality of light emitting diode is indirectly communicated through the graphic openings after reflecting from the first angular surface and the second angular surface.