Disclosed are a Micro LED micro-display chip and a manufacturing method thereof. The Micro LED micro-display chip includes a driver panel; multiple LED units arranged on the driver panel, wherein the multiple LED units includes multiple LED mesas in a one-to-one correspondence with the multiple LED units, and each of the LED units is independently drivable by the driver panel; a grid structure having multiple grid holes, wherein the multiple grid holes are respectively provided around the multiple LED mesas, and recess areas are formed between the LED mesas and the respective grid holes; a wavelength conversion layer provided on the grid structure, including multiple first wavelength conversion units filling the corresponding recess areas and configured to convert the first color light emitted by the LED units into second color light.

Embodiments provide a quantum dot composition, a display device produced from the quantum dot composition, and a method for manufacturing the quantum dot composition. The quantum dot composition includes a scatterer, a first quantum dot including a first core, a second quantum dot including a second core that is different from the first core, a first ligand bonded to a surface of the first quantum dot, a second ligand bonded to the surface of a second quantum dot, and a scatterer ligand bonded to a surface of the scatterer, wherein each of the first ligand and the second ligand each makes a chemical bond to the scatterer ligand.

A display device is provided. The display device includes a circuit substrate and a plurality of pixels. The plurality of pixels are disposed on the circuit substrate, and electrically connected to the circuit substrate. Each of the plurality of pixels includes a first sub-pixel and a second sub-pixel. The first sub-pixel includes at least two first light emitting units connected in series. The second sub-pixel includes at least one second light emitting unit. The number of the at least two first light emitting units of the first sub-pixel is greater than the number of the at least one second light emitting unit of the second sub-pixel. The at least two first light emitting units are electrically connected to a first reference voltage. The at least one second light emitting unit is electrically connected to a second reference voltage. The first reference voltage is different from the second reference voltage.

An LED device, particularly an LED lamp, includes pump LEDs and one or more phosphors allowing the lamp to emit both visible light and SWIR (short-wave infrared) useful in, for example, aviation safety. The emission spectrum of the phosphors provides SWIR light that has high transmission in air with a high water vapor concentration, making it suitable for use with SWIR cameras employed in aircraft. The layout of the LED device also delivers the sufficient visible flux required in aviation safety.

A display panel and a preparation method thereof are provided. In some embodiments, a first film layer and a second film layer are combined, light conversion material is injected from a draining cavity of the second film layer to a groove of the first film layer, the second film layer is then removed, and a light conversion layer is formed within the groove.

A display device includes a display panel that is configured to emit source light, and a light control layer on the display panel. The light control layer includes a partition wall, a red light control part including a first color conversion material, and a green light control part including a second color conversion material. The first color conversion material includes red quantum dots, and the second color conversion material includes green quantum dots. The partition wall includes a lower surface adjacent to the display panel and an upper surface spaced apart from the display panel with the lower surface therebetween. A second maximum distance from a reference surface parallel to the upper surface of the partition wall to the green light control part in a thickness direction may be greater than a first maximum distance from the reference surface to the red light control part.

A display device includes a display panel that is configured to emit source light, and a light control layer on the display panel. The light control layer includes a partition wall, a red light control part including a first color conversion material, and a green light control part including a second color conversion material. The first color conversion material includes red quantum dots, and the second color conversion material includes green quantum dots. The partition wall includes a lower surface adjacent to the display panel and an upper surface spaced apart from the display panel with the lower surface therebetween. A second maximum distance from a reference surface parallel to the upper surface of the partition wall to the green light control part in a thickness direction may be greater than a first maximum distance from the reference surface to the red light control part.

A lighting device, including: a lamp housing and a lamp cap connected to each other and formed a closed space; at least one light-emitting diode filament disposed in the closed space; and a stem connected to the lamp cap and electrical conducted with the light-emitting diode filament, wherein the light-emitting diode filament includes: a chip strip structure; a light conversion unit wrapping the chip strip structure; and electrodes located at two ends of the chip strip structure respectively and electrically connected thereto, wherein at least part of the electrodes are wrapped in the light conversion unit; the chip strip structure includes a substrate with a first end and a second end, and a deposition segment located between the first end and the second end; and the deposition segment includes a plurality of deposition units with a connecting layer disposed therebetween, and a conductor layer electrically connects the deposition units.

A light-emitting element including a first light-emitting diode chip emitting light having a first peak wavelength; a second light-emitting diode chip emitting light having a second peak wavelength longer than the first peak wavelength; a first wavelength conversion material on the first light-emitting diode chip; and a second wavelength conversion material on the second light-emitting diode chip, in which the peak wavelength of the excitation spectrum of the first wavelength conversion material is closer to a first peak wavelength than a second peak wavelength, and the peak wavelength of the excitation spectrum of the second wavelength conversion material is closer to the second peak wavelength than the first peak wavelength.

Provided are a method for using a white light source, and a white light source, wherein precise control of daily rhythm and pleasant lighting can be safely and easily realized in a place of living such as a general home. An embodiment provides a method for using a white light source. Provided that: amounts of stimulation light emitted from a white light source to the intrinsically photosensitive retinal ganglion cells (ipRGCs) and visual cells of the L cone and M cone, among the visual cells of human, are defined as a melanopic irradiance, an L-cone opic irradiance, and an M-cone opic irradiance, respectively; a ratio of the amounts of the stimulation light is expressed by the following formula (1); and A is the ratio corresponding to the emission spectrum of the white light source, and B is the ratio corresponding to the radiation spectrum of a black body having the same color temperature as the white light source, an amount of stimulation light emitted to the ipRGC is quantitatively changed by changing the emission intensity of the white light source satisfying the following formula (2). Melanopic irradiance/(L-cone opic irradiance+M-cone opic irradiance) (1) 0.88A/B1.11 (2)