The method comprises the following successive steps: depositing sintering material (26) onto one of an electronic component (28) and a substrate (30); heating the material (26) so as to bring a temperature of the material to a preliminary exothermic peak, which precedes an exothermic sintering peak, without the temperature of the material reaching a maximum of the preliminary exothermic peak; fastening the other of the component (28) and the substrate (30) to the material (26) so that the material is interposed between the component and the substrate; and pressing the material (26) while hot so as to cause it to creep.

Electronic assembly methods and structures are described. In an embodiment, an electronic assembly method includes bringing together an electronic component and a routing substrate, and directing a large area photonic soldering light pulse toward the electronic component to bond the electronic component to the routing substrate.

At least some embodiments of the present disclosure relate to a semiconductor device package. The semiconductor device package includes a first substrate, an electrical component disposed on the first substrate, a second substrate disposed over the electrical component, an adhesive layer, a spacer, and an encapsulation layer. The adhesive layer is disposed between the electrical component and the second substrate. The spacer directly contacts both the adhesive layer and the second substrate. The encapsulation layer is disposed between the first substrate and the second substrate.

Embodiments of the present disclosure provide an anisotropic conductive film and a forming method thereof, an ACF roll, a bonding structure and a display device. The anisotropic conductive film (ACE) includes: an insulating adhesive layer, including a plurality of preset regions corresponding to electrodes to be bonded and spaced from each other; and capsule structures, dispersed in the insulating adhesive layer of the plurality of preset regions and configured to realize a electrical connection in a direction perpendicular to a surface of the ACF when the ACF is subjected to a pressure in the direction perpendicular to the surface of the ACF, wherein a number of the capsule structures in each of the plurality of preset regions is greater than a preset number.

A method may include providing a chip carrier having a chip supporting region to support a chip, and a chip contacting region having at least one contact pad, the chip carrier being thinner in the chip contacting region such that a first thickness of the chip carrier at the at least one contact pad is smaller than a second thickness of the chip carrier in the chip supporting region. A disposing of the chip, having at least one contact protrusion, over the chip carrier, such that the at least one contact protrusion is arranged over the at least one contact pad may be included. In addition, a pressing of the chip against the chip carrier such that the at least one contact protrusion extends at least partially into the chip contacting region and is electrically contacted to the at least one contact pad may be included.

An electronic device includes a first electronic part that includes a first terminal, a second electronic part disposed to be opposed to the first electronic part, the second electronic part that includes a second terminal including a first end part in contact with the first terminal and a second end part located on an outside of the first terminal, and an adhesive disposed between the first electronic part and the second electronic part, the adhesive maintaining the contact between the first terminal and the first end part by bonding the first electronic part and the second electronic part to each other.

An electronic device and a method for producing an electronic device are disclosed. In an embodiment the electronic device includes a first component and a second component and a sinter layer connecting the first component to the second component, the sinter layer comprising a first metal, wherein at least one of the components comprises at least one contact layer which is arranged in direct contact with the sinter layer, which comprises a second metal different from the first metal and which is free of gold.

An electronic device and a method for producing an electronic device are disclosed. In an embodiment the electronic device includes a first component and a second component and a sinter layer connecting the first component to the second component, the sinter layer comprising a first metal, wherein at least one of the components comprises at least one contact layer which is arranged in direct contact with the sinter layer, which comprises a second metal different from the first metal and which is free of gold.

A module collection and deposition system comprises a container, a module source wafer comprising modules released from the module source wafer, a module collection device operable to remove the modules from the module source wafer and dispose the modules as a disordered and dry collection into the container, and a module deposition device for removing the modules from the container and randomly disposing the modules on a receiving surface. Each module comprises an electronically active unpackaged component.

A module collection and deposition system comprises a container, a module source wafer comprising modules released from the module source wafer, a module collection device operable to remove the modules from the module source wafer and dispose the modules as a disordered and dry collection into the container, and a module deposition device for removing the modules from the container and randomly disposing the modules on a receiving surface. Each module comprises an electronically active unpackaged component.