A process of forming a semiconductor device is disclosed, where the semiconductor device provides a base and a semiconductor chip that is mounted on the base through solder. The process includes steps of: (a) melting the solder by a heater that is provided within a block of a bonding apparatus, where the block mounts the base thereon and the base provides the solder thereon; (b) heating the semiconductor chip by radiation beams in advance to mount the semiconductor chip onto the base; and (c) placing the semiconductor chip onto the melted solder.

The invention concerns a method of flip-chip assembly between first (1) and second (2) components each comprising connection pads (11, 21) on one of the faces of same, referred to as assembly faces, which involves transferring the components onto each other via the assembly faces of same in such a way as to create electrical interconnections between the pads of the first and second components. The invention involves transforming the copper oxide into copper by UV annealing, very locally, in the gap between the components, at least around the areas adjacent to the connection pads. The method according to the invention can be used for any component that is transparent to UV rays, including for substrates made from a plastic material such as substrates made from PEN or PET. The invention also concerns the assembly of two components obtained by the method.

An electroconductive adhesive comprising a plurality of metal fine particles A that each comprise a protective layer, wherein: (a) the metal fine particles A comprise two or more different types of particles, each coated with a C5-C7 monoalkylamine, wherein the two or more different types of particles comprise: (i) a first type of particle having an average particle diameter of 100-300 nm, and (ii) a second type of particle having an average particle diameter of 30-100 nm; and (b) the protective layer suppresses mutual aggregation of the metal fine particles A. Also disclosed are sintered objects of the electroconductive adhesive, methods of manufacturing the electroconductive adhesive and methods of bonding members with the electroconductive adhesive.

An electroconductive adhesive comprising a plurality of metal fine particles A that each comprise a protective layer, wherein: (a) the metal fine particles A comprise two or more different types of particles, each coated with a C5-C7 monoalkylamine, wherein the two or more different types of particles comprise: (i) a first type of particle having an average particle diameter of 100-300 nm, and (ii) a second type of particle having an average particle diameter of 30-100 nm; and (b) the protective layer suppresses mutual aggregation of the metal fine particles A. Also disclosed are sintered objects of the electroconductive adhesive, methods of manufacturing the electroconductive adhesive and methods of bonding members with the electroconductive adhesive.

A method for die bonding an LED chip includes S1: forming a preset adhesive droplet array corresponding to one pad on a substrate based on the area S of one LED chip and the radius R of an adhesive droplet formed by a dispensing device in a single dispensing action, where parameters of the preset adhesive droplet array include the number X of adhesive droplets in a horizontal direction, the number Y of adhesive droplets in a vertical direction, and a horizontal distance H between two horizontally adjacent adhesive droplets, and a vertical distance D between two vertically adjacent adhesive droplets; S2: dispensing a conductive adhesive onto the pad multiple times according to the preset adhesive droplet array to form a bonding portion; and S3: placing the LED chip on the bonding portion and curing the conductive adhesive.