An LED component comprises a plurality of fused light-emitting diodes (LEDs) (e.g., micro-transfer printable or micro-transfer printed LEDs). Each fused LED comprises an LED with first and second LED electrical connections for providing power to the LED and a fuse with first and second fuse electrical connections. The first LED electrical connection is electrically connected to the first electrode. The first fuse electrical connection is electrically connected to the second LED electrical connection and the second fuse electrical connection is electrically connected to the second electrode. A fused LED source wafer comprises an LED wafer having a patterned sacrificial layer forming an array of sacrificial portions separated by anchors and a plurality of fused LED components, each fused LED component disposed entirely on or over a corresponding sacrificial portion. A light-emission system comprises a system substrate and a plurality of fused LED components disposed on or over the system substrate.

The present invention provides a method for detecting an ultra-small defect on a wafer surface, film layer having ultra-small defect that causes abnormalities on the surface of the film layer; form a photoresist pattern with a pattern defect; etching the film layer according to the photoresist pattern to form a film layer pattern with an enlarged defect; and scanning the film layer pattern by using a defect scanner to capture the enlarged defect. In this method, enlarging the size of the ultra-fine particle defect through the exposure defocusing principle; or by adding the photomask consisting of the repeating units, using the repetition pattern as the exposure pattern and combing with the repeating cell to cell comparison method, the capture ability of the detection machine is further improved. Therefore, it can be detected by amplifying the defects of ultrafine particles which cannot be detected by conventional methods.

A method for manufacturing an electronic device includes providing a substrate, forming a plurality of connecting pads and a plurality of conductive portions partially overlapped by the plurality of connecting pads on a surface of the substrate; forming a plurality of conductive lines on the substrate, wherein the plurality of conductive lines are electrically connected to the plurality of conductive portions; and bonding a plurality of light emitting units to the plurality of connecting pads. The method may further includes identifying a defective light emitting unit from the plurality of light emitting units; removing the defective light emitting unit from a corresponding position on the substrate; and bonding-another light emitting unit to the corresponding position.

A method for improving the performance of an image sensor array includes performing an electrical test on the image sensor array, generating a test image from the electrical test to detect an open circuit in a data line of the image sensor array, performing a laser-weld operation the data line to weld a portion of the data line to ground, re-testing the image sensor array to confirm a successful laser-weld operation, performing a laser-cut on a readout portion of the data line, and re-testing the image sensor array to confirm a successful laser-cut operation.

A method for manufacturing a photoelectric conversion device, that includes: forming a laminate structure of a substrate, a transparent electrode, an active layer produced by wet-coating, and a counter electrode, stacked in this order; and thereafter forming a cavity by: (a) pressing an adhesive material just against a defect formed on the surface of said counter electrode, and then peeling off said adhesive material together with said defect and the peripheral part thereof; or (b) sucking a defect formed on the surface of said counter electrode, so as to remove said defect and the peripheral part thereof, where said cavity penetrates through the counter electrode and unreached to the transparent electrode.

A first defect map representing defects in a first semiconductor specimen in an attribute hyperspace may be received. Scores may be assigned to classified defects in the first defect map where an assigned score of a given defect of the classified defects in the first defect map is indicative of a number of defects within a threshold distance in the attribute hyperspace to the given defect in the first defect map that are classified to a same defect class as the given defect. A second defect map representing defects in a second semiconductor specimen in the attribute hyperspace may be received. Defects in the second defect map may be selected for review based on the scores assigned to the classified defects in the first defect map. The selected defects in the second defect map may be selected for classification.

A method for fabricating a wafer includes providing a wafer table, wherein the wafer table includes support pins that are movable with respect to each other; identifying features of a layer to be formed on a wafer, wherein the features have a tolerance for overlay errors below a threshold; moving one or more support pins based on the features; after the moving of the one or more support pins, mounting the wafer on the wafer table; and after the mounting of the wafer on the wafer table, forming the layer on the wafer.

Embodiments of the present disclosure relate to methods for defect inspection. After pattern features are formed in a structure layer, a dummy filling material having dissimilar optical properties from the structure layer is filled in the pattern features. The dissimilar optical properties between materials in the pattern features and the structure layer increase contrast in images captured by an inspection tool, thus increasing the defect capture rate.

A method for producing an optoelectronic device is disclosed. The method include preforming an inductive excitation of a current by an inductive component of the optoelectronic device such that the optoelectronic device emits electromagnetic radiation, measuring of at least one electro-optical characteristic of the optoelectronic device and applying a converter material to an emission side of the optoelectronic device, wherein a quantity of the converter material is determined from the measurement of the electro-optical characteristic.

According to an embodiment, a template includes a flat plate-shaped first member, a flat plate-shaped second member including a pattern arrangement face, and a flat plate-shaped third member provided with an opening at a position corresponding to an arrangement position of the second member. The template is dividable at a position of at least one of a first boundary between the first member and the second member and a second boundary between the first member and the third member.