A micro LED display manufacturing method according to various embodiments may include: a first operation of bonding an anisotropic conductive film including a plurality of conductive particles onto one surface of a prepared substrate, the one surface including a circuit part; a second operation of forming a bonding layer on the anisotropic conductive film; a third operation of positioning a plurality of micro LED chips above the bonding layer, the micro LED chips being arranged on a carrier substrate while being spaced a first distance apart from the substrate; a fourth operation of attaching the plurality of micro LED chips onto the bonding layer by means of laser transfer; and a fifth operation of forming a conductive structure for electrically connecting a connection pad to the circuit part through the conductive particles by means of heating and pressurizing.

An arrangement is disclosed. In one example, the arrangement of a conductor and an aluminum layer soldered together comprises a substrate and the aluminum layer disposed over the substrate. The aluminum forms a first bond metal. An intermetallic compound layer is disposed over the aluminum layer. A solder layer is disposed over the intermetallic compound layer, wherein the solder comprises a low melting majority component. The conductor is disposed over the solder layer, wherein the conductor has a soldering surface which comprises a second bond metal. The intermetallic compound comprises aluminum and the second bond metal and is predominantly free of the low melting majority component.

An integrated circuit package system includes a substrate, a plurality of leads, N semiconductor devices, N first heat sinks, an encapsulating body, a second heat sink and a plurality of heat-dissipating fins protruding upward from the second heat sink, where N is a natural number. The leads are formed on a lower surface of the substrate. Each of the semiconductor devices is attached on an upper surface of the substrate, and includes a plurality of bonding pads which each is electrically connected to the corresponding lead. Each first heat sink is thermally coupled to a first top surface of the corresponding semiconductor device. The encapsulating body is formed to cover the substrate, the N semiconductor devices and the N first heat sinks such that the leads are exposed. The second heat sink is mounted on the encapsulating body, and is thermally coupled to the N first heat sinks.

Radio frequency (RF) power dies having flip-chip architectures are disclosed, as are power amplifier modules (PAMs) containing such RF power dies. Embodiment of the PAM include a module substrate and an RF power die, which is mounted to a surface of the module substrate in an inverted orientation. The RF power die includes, in turn, a die body having a frontside and an opposing backside, a transistor having active regions formed in the die body, and a frontside layer system formed over the die body frontside. The frontside layer system contains patterned metal layers defining first, second, and third branched electrode structures, which are electrically coupled to the active regions of the transistor. A frontside input/output interface is formed in an outer terminal portion of the frontside layer system and contains first, second, and third bond pads electrically coupled to the first, second, and third branched electrode structures, respectively.

Radio frequency (RF) power dies having flip-chip architectures are disclosed, as are power amplifier modules (PAMs) containing such RF power dies. Embodiment of the PAM include a module substrate and an RF power die, which is mounted to a surface of the module substrate in an inverted orientation. The RF power die includes, in turn, a die body having a frontside and an opposing backside, a transistor having active regions formed in the die body, and a frontside layer system formed over the die body frontside. The frontside layer system contains patterned metal layers defining first, second, and third branched electrode structures, which are electrically coupled to the active regions of the transistor. A frontside input/output interface is formed in an outer terminal portion of the frontside layer system and contains first, second, and third bond pads electrically coupled to the first, second, and third branched electrode structures, respectively.

A semiconductor package includes a substrate, a semiconductor chip and a heat dissipation structure. The semiconductor chip includes a first surface, a second surface opposite to the first surface, and at least one chip pad disposed adjacent to the first surface. The chip pad is electrically connected to the substrate. The heat dissipation structure is disposed adjacent to the second surface of the semiconductor chip and a portion of the substrate. An area of the heat dissipation structure is greater than an area of the semiconductor chip.

Disclosed is a method for transient liquid-phase bonding between metal materials using a magnetic force. In particular, in the method, a magnetic force is applied to a transient liquid-phase bonding process, thereby shortening a transient liquid-phase bonding time between the metal materials, and obtaining high bonding strength. To this end, an attractive magnetic force is applied to a ferromagnetic base while a repulsive magnetic force is applied to a diamagnetic base, thereby to accelerate diffusion. This may reduce a bonding time during a transient liquid-phase bonding process between two bases and suppress formation of Kirkendall voids and voids and suppress a layered structure of an intermetallic compound, thereby to increase a bonding strength.

Disclosed is a method for transient liquid-phase bonding between metal materials using a magnetic force. In particular, in the method, a magnetic force is applied to a transient liquid-phase bonding process, thereby shortening a transient liquid-phase bonding time between the metal materials, and obtaining high bonding strength. To this end, an attractive magnetic force is applied to a ferromagnetic base while a repulsive magnetic force is applied to a diamagnetic base, thereby to accelerate diffusion. This may reduce a bonding time during a transient liquid-phase bonding process between two bases and suppress formation of Kirkendall voids and voids and suppress a layered structure of an intermetallic compound, thereby to increase a bonding strength.

A package includes a carrier substrate, a first die, and a second die. The first die includes a first bonding layer, a second bonding layer opposite to the first bonding layer, and an alignment mark embedded in the first bonding layer. The first bonding layer is fusion bonded to the carrier substrate. The second die includes a third bonding layer. The third bonding layer is hybrid bonded to the second bonding layer of the first die.

A package includes a carrier substrate, a first die, and a second die. The first die includes a first bonding layer, a second bonding layer opposite to the first bonding layer, and an alignment mark embedded in the first bonding layer. The first bonding layer is fusion bonded to the carrier substrate. The second die includes a third bonding layer. The third bonding layer is hybrid bonded to the second bonding layer of the first die.