Process for manufacturing a chip-card module. It includes one or more operations in which a meltable solder is deposited on connection pads formed in a layer of electrically conductive material located on the back side of a dielectric substrate, and at least one electronic component is connected to these connection pads by reflowing the solder. Chip-card module obtained using this process. Chip card including such a module.

Provided is a method of fabricating a semiconductor package. The method of fabricating the semiconductor package include preparing a lower element including a lower substrate, a lower electrode, an UBM layer, and a reducing agent layer, providing an upper element including an upper substrate, an upper electrode, and a solder bump layer, providing a pressing member on the upper substrate to press the upper substrate to the lower substrate, and providing a laser beam passing through the pressing member to bond the upper element to the lower element.

An electronic device includes a first electronic part, a second electronic part opposite the first electronic part, and a bonding portion between the first electronic part and the second electronic part. The bonding portion contains a solder containing a substance whose crystal structure reversibly changes in temperature rise and fall processes which accompany the operation of the electronic device or electronic equipment including the electronic device. A change in the crystal structure of the substance contained in the solder promotes recovery and recrystallization of the solder in the temperature rise and fall processes which accompany the operation of the electronic device or the electronic equipment. As a result, the coarsening of crystal grains in the solder is suppressed.

An electronic device includes a first electronic part, a second electronic part opposite the first electronic part, and a bonding portion between the first electronic part and the second electronic part. The bonding portion contains a solder containing a substance whose crystal structure reversibly changes in temperature rise and fall processes which accompany the operation of the electronic device or electronic equipment including the electronic device. A change in the crystal structure of the substance contained in the solder promotes recovery and recrystallization of the solder in the temperature rise and fall processes which accompany the operation of the electronic device or the electronic equipment. As a result, the coarsening of crystal grains in the solder is suppressed.

An electronic device includes a first electronic part, a second electronic part opposite the first electronic part, and a bonding portion between the first electronic part and the second electronic part. The bonding portion contains a solder containing a substance whose crystal structure reversibly changes in temperature rise and fall processes which accompany the operation of the electronic device or electronic equipment including the electronic device. A change in the crystal structure of the substance contained in the solder promotes recovery and recrystallization of the solder in the temperature rise and fall processes which accompany the operation of the electronic device or the electronic equipment. As a result, the coarsening of crystal grains in the solder is suppressed.

An electronic device includes a first electronic part, a second electronic part opposite the first electronic part, and a bonding portion between the first electronic part and the second electronic part. The bonding portion contains a solder containing a substance whose crystal structure reversibly changes in temperature rise and fall processes which accompany the operation of the electronic device or electronic equipment including the electronic device. A change in the crystal structure of the substance contained in the solder promotes recovery and recrystallization of the solder in the temperature rise and fall processes which accompany the operation of the electronic device or the electronic equipment. As a result, the coarsening of crystal grains in the solder is suppressed.

Provided are a hybrid bonding structure, a solder paste composition, a semiconductor device, and a method of manufacturing the semiconductor device. The hybrid bonding structure includes a solder ball and a solder paste bonded to the solder ball. The solder paste includes a transient liquid phase. The transient liquid phase includes a core and a shell on a surface of the core. A melting point of the shell may be lower than a melting point of the core. The core and the shell are configured to form an intermetallic compound in response to the transient liquid phase at least partially being at a temperature that is within a temperature range of about 20 C. to about 190 C.