Discussed is a device for self-assembling semiconductor light-emitting diodes for placing the semiconductor light-emitting diodes at predetermined positions on a substrate by using an electric field and a magnetic field, the substrate being accommodated in an assembly chamber accommodating a fluid, the device including a substrate chuck configured to dispose the substrate at an assembly position, wherein the substrate chuck includes a substrate support part configured to support the substrate on which an assembly electrode is formed, a rotating part configured to support the substrate support part, and a controller configured to control driving of the substrate chuck, wherein the substrate support part includes micro-holes for injecting a gas between the fluid and the substrate, and wherein the controller controls whether the gas is injected through the micro-holes according to whether the substrate is raised or lowered.

The invention relates to a bonding tool for a bonding device for bonding at least one component by adhesives to a substrate, the bonding device including a circular disc-shaped main body lying in a main plane and having an opening and a receiving head connected to the main body for receiving and holding the components, an orthogonal projection of the receiving head onto the main plane lying within the opening so that the receiving head is freely accessible through the opening. The bonding tool has a lighting unit integrated in the bonding tool for curing the adhesive. The invention also relates to a bonding device for bonding at least one component by adhesives applied to a substrate located in an assembly position, and to a bonding method for bonding components by adhesives applied to a substrate.

Discussed is a device for self-assembling semiconductor light-emitting diodes includes a substrate chuck that is provided in an assembly chamber and supports a substrate and disposes the substrate at an assembly position, wherein the substrate chuck sucks or injects a gas present between the substrate and a fluid during loading and unloading of the substrate.

A method for bonding a first substrate to a second substrate on mutually facing contact surfaces of the substrates includes a device in which the first substrate is mounted on a first chuck and the second substrate is mounted on a second chuck. A plate is arranged between the second substrate and the second chuck. The second substrate with the plate is deformed with respect to the second chuck before and/or during the bonding.

An electronic device is provided, the electronic device includes a driving substrate, the driving substrate includes a plurality of circular grooves and a plurality of rectangular grooves, a plurality of disc-shaped light-emitting units, at least one disc-shaped light-emitting unit is disposed in at least one circular groove, and the at least one disc-shaped light-emitting unit includes an alignment element positioned on a top surface of the at least one disc-shaped light-emitting unit, a diameter of the at least one disc-shaped light-emitting unit is defined as R, a diameter of the alignment element is defined as r, a width of at least one rectangular groove among the rectangular grooves is defined as w, and a height of the at least one rectangular groove is defined as H, and the at least one disc-shaped light-emitting unit and the at least one rectangular groove satisfy the condition of (R+r)/2>(w.sup.2+H.sup.2).sup.1/2.

A chip-carrying structure and a chip-bonding method are provided. The chip-carrying structure includes a circuit substrate for carrying a plurality of conductive materials, a plurality of micro heaters disposed on or inside the circuit substrate, and a micro heater control chip electrically connected to the micro heaters. Therefore, when a chip is disposed on two corresponding ones of the conductive materials, the micro heater control chip is configured to control a corresponding one of the micro heaters to start or stop heating the two corresponding conductive materials according to chip movement information of the chip.

A composite assembly of three stacked joining partners, and a corresponding method. The three stacked joining partners are materially bonded to one another by an upper solder layer and a lower solder layer. An upper joining partner and a lower joining partner are fixed in their height and have a specified distance from one another. The upper solder layer is fashioned from a first solder agent, having a first melt temperature, between the upper joining partner and a middle joining partner. The second solder layer is fashioned from a second solder agent, having a higher, second melt temperature, between the middle joining partner and the lower joining partner. The upper joining partner has an upwardly open solder compensating opening filled with the first solder agent, from which, to fill the gap between the upper joining partner and the middle joining partner, the first solder agent subsequently flows into the gap.

A bonding device (100) bonds at least one component (C) to a substrate (B) using a metal material (M). The bonding device (100) includes a wall section (20), at least one pressing section (40), and a rotational shaft (30). The rotational shaft (30) is fixed to the wall section (20). Each pressing section (40) has an arm (42) and a presser (43) or a substrate supporting member (90). The arm (42) extends from the rotational shaft (30). The arm (42) pivots about the rotational shaft (30). The presser (43) presses the component (C). The substrate supporting member (90) is disposed on a reference surface (142). The substrate supporting member (90) supports the substrate (B). The component (C) is bonded to the substrate (B) through point contact of the presser (43) with the component (C) or point contact of the substrate supporting member (90) with the reference surface (142).

A method of liquid assisted bonding includes: forming a structure with a liquid layer between an electrode of a device and a contact pad of a substrate, and two opposite surfaces of the liquid layer being respectively in contact with the electrode and the contact pad in which hydrogen bonds are formed between the liquid layer and at least one of the electrode and the contact pad; and evaporating the liquid layer to break said hydrogen bonds such that at least one of a surface of the electrode facing the contact pad and a surface of the contact pad facing the electrode is activated so as to assist a formation of a diffusion bonding between the electrode of the device and the contact pad in which a contact area between the electrode and the contact pad is smaller than or equal to about 1 square millimeter.

Discussed is a substrate chuck including: a substrate support part for supporting a substrate having an assembly electrode; a vertical moving part which moves the substrate so that one surface of the substrate comes in contact with a fluid in a state in which the substrate is supported by the substrate support; an electrode connection part for applying power to the assembly electrode to generate an electric field so that semiconductor light-emitting diodes are placed at the predetermined positions of the substrate in a process of moving the semiconductor light-emitting diodes by a position change of at least one magnet; and a rotating part for rotating the substrate support part around a rotating shaft so that the substrate is placed in an upward or downward direction, wherein the rotating shaft is spaced apart from a center of the substrate support part at a predetermined distance.