A chip mounting structure and a chip mounting device are provided. The chip mounting structure includes a circuit substrate and a plurality of micro heaters. The circuit substrate has a plurality of solder pads. A plurality of micro heaters are disposed on the circuit substrate adjacent to the solder pad. The plurality of chips are disposed on the circuit substrate, and the chip is electrically connected to the solder pad by a solder ball. Therefore, the soldering yield of the process can be reduced by the chip mounting structure and the chip mounting device.

Provided are a mass transfer device and a mass transfer method. The mass transfer device is provided with multiple channels, a first opening of each channel is arranged on a first surface of the mass transfer device, a second opening of each channel is arranged on a second surface of the mass transfer device, and the distances between the channels are gradually increased along a direction from the first surface to the second surface. In the provided mass transfer method, through a laser irradiation mode, the Micro-LEDs are separated from the first substrate and enter the channels of the mass transfer device through the first openings, and falling into Micro-LED to-be-installed positions on a second substrate through the second openings of the channels, thereby transferring the Micro-LEDs from the first substrate to the second substrate.

A semiconductor device includes a semiconductor wafer. A plurality of pillar bumps is formed over the semiconductor wafer. A solder is deposited over the pillar bumps. The semiconductor wafer is singulated into a plurality of semiconductor die after forming the pillar bumps while the semiconductor wafer is on a carrier. An encapsulant is deposited around the semiconductor die and pillar bumps while the semiconductor die remains on the carrier. The encapsulant covers an active surface of the semiconductor die between the pillar bumps.

A semiconductor device includes a semiconductor wafer. A plurality of pillar bumps is formed over the semiconductor wafer. A solder is deposited over the pillar bumps. The semiconductor wafer is singulated into a plurality of semiconductor die after forming the pillar bumps while the semiconductor wafer is on a carrier. An encapsulant is deposited around the semiconductor die and pillar bumps while the semiconductor die remains on the carrier. The encapsulant covers an active surface of the semiconductor die between the pillar bumps.

Provided are a mass transfer device and a mass transfer method. The mass transfer device is provided with multiple channels, a first opening of each channel is arranged on a first surface of the mass transfer device, a second opening of each channel is arranged on a second surface of the mass transfer device, and the distances between the channels are gradually increased along a direction from the first surface to the second surface. In the provided mass transfer method, through a laser irradiation mode, the Micro-LEDs are separated from the first substrate and enter the channels of the mass transfer device through the first openings, and falling into Micro-LED to-be-installed positions on a second substrate through the second openings of the channels, thereby transferring the Micro-LEDs from the first substrate to the second substrate.

A method for manufacturing a display panel includes providing a backplate, forming bonding parts on backplate, forming an auxiliary layer on backplate, releasing light-emitting elements onto the auxiliary layer such that electrodes of the light-emitting elements are in contact with the first parts to form an intermediate backplate, arranging the intermediate backplate under first predetermined condition under which a fluidity of the first part is greater than that of the second part, and bonding the electrodes and the bonding parts to form an eutectic bonding layer, and arranging the intermediate backplate under second predetermined condition such that the first and second parts form solid-state first and second members. The backplate includes first and second regions. The bonding parts are located in the first regions. The auxiliary layer covers the backplate and the bonding parts. The auxiliary layer includes first and second parts respectively located in the first and second regions.

A light-emitting device includes a carrier, a light-emitting element and a connection structure. The carrier includes a first electrical conduction portion. The light-emitting element includes a first light-emitting layer capable of emitting first light and a first contact electrode formed under the light-emitting layer. The first contact electrode is corresponded to the first electrical conduction portion. The connection structure includes a first electrical connection portion and a protective portion surrounding the first contact electrode and the first electrical connection portion. The first electrical connection portion includes an upper portion, a lower portion and a neck portion arranged between the upper portion and the lower portion. The lower portion has a width is wider than of the upper portion.

Provided is a method of manufacturing a micro light emitting device array. The method includes forming a display transfer structure including a transfer substrate and a plurality of micro light emitting devices, where the transfer substrate includes at least two first alignment marks; preparing a driving circuit board, the driving circuit board including a plurality of driving circuits and at least two second alignment marks, arranging the display transfer structure and the driving circuit board to face each other so that the at least two first alignment marks and the at least two second alignment marks face one another and bonding the plurality of micro light emitting devices of the display transfer structure to the plurality of driving circuits.

Provided are a micro light emitting diodes and a method of transferring the same. The method includes providing an array substrate with the micro light emitting diodes; adhering abnormal micro light emitting diodes of the array substrate on a first carrying plate; adhering the abnormal micro light emitting diodes on the first carrying plate to a laser deformation glue layer of a second carrying plate; irradiating the laser deformation glue layer by a laser to flip the abnormal micro light emitting diodes; transferring the abnormal micro light emitting diodes from the second carrying plate to a third carrying plate; and transferring again to the array substrate.

A wet alignment method for a micro-semiconductor chip and a display transfer structure are provided. The wet alignment method for a micro-semiconductor chip includes: supplying a liquid to a transfer substrate including a plurality of grooves; supplying the micro-semiconductor chip onto the transfer substrate; scanning the transfer substrate by using an absorber capable of absorbing the liquid. According to the wet alignment method, the micro-semiconductor chip may be transferred onto a large area.