The present disclosure provides a quantum dot color filter, a fabrication method thereof, a display panel and a display device, and belongs to the field of display technology. The quantum dot color filter of the present disclosure includes a quantum dot functional layer configured to emit light of a certain color under excitation of excitation light. The quantum dot functional layer has a hollowed-out portion, which exposes a side surface of the quantum dot functional layer, so that the excitation light is able to arrive at the side surface.

A photo nanoimprint lithography (P-NIL) resin is disclosed. The P-NIL resin comprises: a cross-linkable organic binder; solvent based inorganic nanoparticles dispersed in the P-NIL resin; and a solvent configured to be evaporated; the P-NIL resin having a viscosity in the range of 4,000 to 6,000 centipoise at 25° C. after the solvent is evaporated prior to curing the P-NIL resin; and the P-NIL resin having a refractive index of greater than 1.6 at 589 nm and glass transition temperature of greater than 50° C. after curing by a photo initiator

A mask and a method of manufacturing the same, an evaporation apparatus and a display device are provided. The method includes forming a first photoresist pattern on a substrate, the first photoresist pattern including a plurality of photoresist structures, each photoresist structure including a first surface away from the substrate and a second surface near the substrate, and the size of the first surface being smaller than that of the second surface; forming a metal layer on the substrate with the first photoresist pattern, the metal layer including a plurality of recessed regions and a plurality of raised regions; forming a second photoresist pattern in the recessed regions, an orthographic projection of the second photoresist pattern on the metal layer overlapping with the recessed regions; removing regions of the metal layer not covered by the second photoresist pattern, the second photoresist pattern, the substrate and the first photoresist pattern mask.

The present invention provides an imprint apparatus including a holding unit configured to hold a material, a measurement unit configured to measure a position of the material held by the holding unit, a detection unit configured to detect dechucking of the material in the holding unit, and a control unit configured to control continuation processing for continuing an imprint process if the detection unit has detected the dechucking, wherein the control unit performs, as the continuation processing, processing of causing the holding unit to hold the dechucked material again without unloading the material from the imprint apparatus, and processing of measuring, by the measurement unit, a position of the material held again by the holding unit before the imprint process to use the position for alignment in the imprint process.

A nanofabrication method comprises receiving information regarding a distortion within an imprint system, generating a first drop pattern of formable material based on the received information, dispensing a first plurality of drops onto a substrate according to the first drop pattern, contacting the dispensed first plurality of drops with a patternless superstrate to form a first layer of formable material, forming a first cured layer by curing the first layer of formable material while the superstrate is contacting the first layer of formable material, separating the superstrate from the first cured layer, depositing an etch resistant layer on the first cured layer, generating a second drop pattern of formable material, dispensing a second plurality of drops onto the etch resistant layer according to the second drop pattern, and contacting the dispensed second plurality of drops with a patterned template to form a second layer of formable material.

An apparatus for removing a pellicle frame from a photomask includes a heater configured to soften an adhesive between the pellicle frame and the photomask; a shower head including a plate, a central region of the plate is configured to overlap with a pattern area of the photomask, and a periphery region of the plate is configured to provide a flow from the periphery region of the plate toward the pellicle frame and the adhesive; and a gripper configured to secure the pellicle frame against the flow and remove the adhesive and the pellicle frame from the photomask. A method of removing a pellicle frame, includes providing a plate overlapped with a pattern area of the photomask; providing a flow from the plate toward the pellicle frame and an adhesive; securing the pellicle frame; soften the adhesive; and leveraging the pellicle frame to remove the adhesive and the pellicle frame.

A method for manufacturing a multi-stage compound eye lens includes the steps of manufacturing a micropillar array using a photoetching method, then sputtering ZnO on the surface of the micropillar array, jet printing an ultraviolet curing adhesive onto gaps in the micropillar array using a micro jet printing machine, and controlling the morphology of microlens using the number of droplet dropping instances to obtain a microlens array; further respectively dissolving hexamethyl tetramine and zinc nitrate in deionized water, then pouring the hexamethyl tetramine solution into the zinc nitrate solution to obtain a mixed solution, placing the microlens array into the mixed solution, and placing is in a water bath kettle for a water bath, and finally, removing the microlens array from the mixed solution, rinsing it with deionized water, and drying same to obtain the multi-stage compound eye lens.

An embodiment of the present disclosure provides a display substrate. The display substrate includes a driver backplane, and a reflective structure and a pixel electrode on the driver backplane. Reflective structure and the pixel electrode are disposed sequentially away from the driver backplane along a thickness direction of the driver backplane. The pixel electrode is connected to the driver backplane through the reflective structure. A surface of the reflective structure away from the driver backplane is a reflective surface comprising a plurality of arc surfaces, and each of the plurality of arc surfaces is convex protruding towards a direction away from the driver backplane. The plurality of the arc surfaces are continuously arranged, and any two adjacent arc surfaces of the plurality of the arc surfaces are connected to each other.

The present specification relates to a compound represented by Chemical Formula 1, a photoresist fluorescent resin composition including the same, and a color conversion film manufactured using the same, a backlight unit and a display apparatus.

The present invention provides a photosensitive composition with which a cured film having excellent patterning properties and excellent electrode anticorrosion properties can be produced. In addition, it also provides a cured film formed of the photosensitive composition, a color filter, a light shielding film, an optical element, a solid-state imaging element, an infrared sensor, and a headlight unit.

The photosensitive composition of the present invention contains a zirconium nitride-based particle containing one or more selected from the group consisting of zirconium nitride and zirconium oxynitride a resin, a polymerizable compound, and a photopolymerization initiator, in which the zirconium nitride-based particle contains 0.001% to 0.400% by mass of a Fe atom with respect to a total mass of the zirconium nitride-based particle.