A microelectronic device is formed by dispensing discrete amounts of a mixture of photoresist resin and solvents from droplet-on-demand sites onto a wafer to form a first photoresist sublayer, while the wafer is at a first temperature which allows the photoresist resin to attain less than 10 percent thickness non-uniformity. The wafer moves under the droplet-on-demand sites in a first direction to form the first photoresist sublayer. A portion of the solvents in the first photoresist sublayer is removed. A second photoresist sublayer is formed on the first photoresist sublayer using the droplet-on-demand sites while the wafer is at a second temperature to attain less than 10 percent thickness non-uniformity in the combined first and second photoresist sublayers. The wafer moves under the droplet-on-demand sites in a second direction for the second photoresist sublayer, opposite from the first direction.

A microelectronic device is formed by dispensing discrete amounts of a mixture of photoresist resin and solvents from droplet-on-demand sites onto a wafer to form a first photoresist sublayer, while the wafer is at a first temperature which allows the photoresist resin to attain less than 10 percent thickness non-uniformity. The wafer moves under the droplet-on-demand sites in a first direction to form the first photoresist sublayer. A portion of the solvents in the first photoresist sublayer is removed. A second photoresist sublayer is formed on the first photoresist sublayer using the droplet-on-demand sites while the wafer is at a second temperature to attain less than 10 percent thickness non-uniformity in the combined first and second photoresist sublayers. The wafer moves under the droplet-on-demand sites in a second direction for the second photoresist sublayer, opposite from the first direction.

A semiconductor device according to the present invention includes a first conductive-type SiC semiconductor layer, and a Schottky metal, comprising molybdenum and having a thickness of 10 nm to 150 nm, that contacts the surface of the SiC semiconductor layer. The junction of the SiC semiconductor layer to the Schottky metal has a planar structure, or a structure with recesses and protrusions of equal to or less than 5 nm.

The present disclosure provides a supporting substrate, including: a base substrate and a plurality of connecting electrodes provided on the base substrate, wherein a clamping electrode is provided on a side of at least one of the connecting electrodes facing away the base substrate, the clamping electrode is electrically connected with a corresponding connecting electrode and configured to be capable of clamping and fixing an electrode pin of the micro-light emitting device. The present disclosure also provides a manufacturing method for the supporting substrate, and a backplane.

A display substrate, including: a base substrate including at least a side edge and a display area; a plurality of pixel units disposed in the display area, a second pixel unit is located on a side of a first pixel unit close to the side edge, edges of the second pixel unit include the side edge, a third pixel unit is located between the first pixel unit and the second pixel unit, and the third pixel unit is adjacent to the second pixel unit; and a plurality of light emitting diode chips disposed on the base substrate a first light emitting diode chip is located in the first pixel unit, a part of a second light emitting diode chip is located in the second pixel unit, and the other part of the second light emitting diode chip is located in the third pixel unit.

A method of manufacturing an electronic device includes providing a substrate, forming a solder on the substrate, and bonding a diode to the substrate through the solder, wherein the solder is formed by stacking a plurality of first conductive layers and a plurality of second conductive layers alternately, and the plurality of first conductive layers and the plurality of second conductive layers include different materials.

A method of manufacturing an electronic device includes providing a substrate, forming a solder on the substrate, and bonding a diode to the substrate through the solder, wherein the solder is formed by stacking a plurality of first conductive layers and a plurality of second conductive layers alternately, and the plurality of first conductive layers and the plurality of second conductive layers include different materials.

A bonded assembly includes a first semiconductor die that includes first metallic bonding structures embedded within a first bonding-level dielectric layer, and a second semiconductor die that includes second metallic bonding structures embedded within a second bonding-level dielectric layer and bonded to the first metallic bonding structures by metal-to-metal bonding. One of the first metallic bonding structures a pad portion, and a via portion located between the pad portion and the first semiconductor device, the via portion having second tapered sidewalls.

A light-emitting substrate, a method of manufacturing a light-emitting substrate, and a display device are provided. The light-emitting substrate includes: a first substrate, wherein the first substrate includes a first base substrate, a light-emitting diode arranged on the first base substrate, and a first conductive pad arranged on the first base substrate; a second substrate arranged opposite to the first substrate, wherein the second substrate includes a second base substrate, and a second conductive pad arranged on the second base substrate; and a bonding wire structure including a bonding wire, wherein the first conductive pad is located on a surface of the first substrate away from the second substrate, the second conductive pad is located on a surface of the second substrate away from the first substrate, and the bonding wire is configured to electrically connect the first conductive pad and the second conductive pad.

A display assembly includes: a display panel including a driving circuit and a first pad; and a flexible circuit board including a flexible base plate, a first wiring layer and a first reinforcement plate. The first wiring layer is on the flexible base plate and includes a main routing portion and a second pad, and the first reinforcement plate is on a side of the first wiring layer distal to the flexible base plate; an orthogonal projection of the main routing portion on the flexible base plate is within an orthogonal projection of the first reinforcement plate on the flexible base plate; the second pad is connected to the main routing portion, and is electrically connected to the first pad; the first reinforcement plate is outside the display panel and has a first edge proximal to the display panel The first edge includes convex and concave portions alternately arranged.