Apparatuses, systems and methods associated with integrated circuit (IC) package design are disclosed herein. In embodiments, an IC package may include a first die and a second die. The IC package may include a spacer located between the first die and the second die, the spacer includes glass , and a molding compound that at least partially encompasses the first die, the second die, and the spacer. Other embodiments may be described and/or claimed.

An embodiment package comprises an integrated circuit die encapsulated in an encapsulant, a patch antenna over the integrated circuit die, and a dielectric feature disposed between the integrated circuit die and the patch antenna. The patch antenna overlaps the integrated circuit die in a top-down view. The thickness of the dielectric feature is in accordance with an operating bandwidth of the patch antenna.

A semi-finished product of a power device including a semiconductor chip and a first solder pad is provided. The semiconductor chip has an active surface and a rear surface opposite to the active surface. The first solder pad is positioned and fixed on a center of the semiconductor chip. The first solder pad is sheet-shaped. The semiconductor chip is connected to the first solder pad with the active surface. A size of the first solder pad is smaller than a size of the semiconductor chip to expose a portion of the semiconductor chip. A manufacturing method of the semi-finished product of the power device and a manufacturing method of the power device are also provided.

The present application provides a semiconductor package and a manufacturing method thereof. The semiconductor package includes a first device, first electrical connectors, a second device and second electrical connectors. The first device is attached to a package substrate. An active side of the first device die faces toward the package substrate. The first electrical connectors connect the active side of the first device die to the package substrate. The second device die is stacked over the first device die. An active side of the second device die faces toward the package substrate. A portion of the active side of the second device die is outside an area that overlaps the first device die. The second electrical connectors connect the portion of the active side of the second device die to the package substrate.

A carrier for an optoelectronic component includes a main body, wherein the main body includes a first electrically conductive heating layer arrangement, a first solder layer for soldering an optoelectronic component to the main body is arranged on a first side of the main body, the first electrically conductive heating layer arrangement is electrically insulated from the first solder layer and thermally connected to the first solder layer, and the first heating layer arrangement has an exposed portion on which molten solder of the first solder layer can flow to reduce an electrical resistance of the first heating layer arrangement.

An embodiment package comprises an integrated circuit die encapsulated in an encapsulant, a patch antenna over the integrated circuit die, and a dielectric feature disposed between the integrated circuit die and the patch antenna. The patch antenna overlaps the integrated circuit die in a top-down view. The thickness of the dielectric feature is in accordance with an operating bandwidth of the patch antenna.

A method of joining a semiconductor die to a substrate includes: applying a solder preform to a metal region of the semiconductor die or to a metal region of the substrate, the solder preform having a maximum thickness of 30 μm and a lower melting point than both metal regions; forming a soldered joint between the metal region of the semiconductor die and the metal region of the substrate via a diffusion soldering process and without applying pressure directly to the die; and setting a soldering temperature of the diffusion soldering process so that the solder preform melts and fully reacts with the metal region of the semiconductor die and the metal region of the substrate to form one or more intermetallic phases throughout the entire soldered joint, each intermetallic phase having a melting point above the melting point of the preform and the soldering temperature.

A method of batch soldering includes: forming a soldered joint between a metal region of a first semiconductor die and a metal region of a substrate using a solder preform via a soldering process which does not apply pressure directly to the first semiconductor die, the solder preform having a maximum thickness of 30 μm and a lower melting point than the metal regions; setting a soldering temperature of the soldering process so that the solder preform melts and fully reacts with the metal region of the first semiconductor die and the metal region of the substrate to form one or more intermetallic phases throughout the entire soldered joint, each intermetallic phase having a melting point above the preform melting point and the soldering temperature; and soldering a second semiconductor die to the same or different metal region of the substrate, without applying pressure directly to the second semiconductor die.

Matching of coefficient of thermal expansion for heat spreaders and carrier die can facilitate optoelectronic die alignment. In one example, an apparatus comprises a carrier die comprising a first coefficient of thermal expansion, two or more optoelectronic die disposed on the carrier die, and a spreader. The spreader can comprise a second material coefficient of thermal expansion matched to the first coefficient of thermal expansion. Additionally, a thermal interface material is disposed between the spreader and the one or more optoelectronic die.

Semiconductor devices may include a first semiconductor chip, a first redistribution layer on a bottom surface of the first semiconductor chip, a second semiconductor chip on the first semiconductor chip, a second redistribution layer on a bottom surface of the second semiconductor chip, a mold layer extending on sidewalls of the first and second semiconductor chips and on the bottom surface of the first semiconductor chip, and an external terminal extending through the mold layer and electrically connected to the first redistribution layer. The second redistribution layer may include an exposed portion. The first redistribution layer may include a first conductive pattern electrically connected to the first semiconductor chip and a second conductive pattern electrically insulated from the first semiconductor chip. The exposed portion of the second redistribution layer and the second conductive pattern of the first redistribution layer may be electrically connected by a first connection wire.