Shielded radio-frequency (RF) module having reduced area. In some embodiments, a method for fabricating a radio-frequency module includes forming or providing a packaging substrate configured to receive a plurality of components. The method may include mounting one or more devices on the packaging substrate such that the packaging substrate includes a first area associated with mounting of each of the one or more devices. In some embodiments, the method further includes forming a plurality of shielding wirebonds on the packaging substrate to provide RF shielding functionality for one or more regions on the packaging substrate, such that the packaging substrate includes a second area associated with formation of each shielding wirebond, the mounting of each device implemented with respect to a corresponding shielding wirebond such that a portion of the first area associated with the device overlaps at least partially with a portion of the second area associated with the corresponding shielding wirebond.

A semiconductor package including: a redistribution layer including redistribution line patterns, redistribution vias connected to the redistribution line patterns, and a redistribution insulating layer surrounding the redistribution line patterns and the redistribution vias; semiconductor chips including at least one upper semiconductor chip disposed on a lowermost semiconductor chip of the semiconductor chips, wherein the at least one upper semiconductor chip is thicker than the lowermost semiconductor chip; bonding wires each having a first end and a second end, wherein the bonding wires connect the semiconductor chips to the redistribution layer, wherein the first end of each of the bonding wires is connected to a respective chip pad of the semiconductor chips and the second end of each of the bonding wires is connected to a respective one of the redistribution line patterns; and a molding member surrounding, on the redistribution layer, the semiconductor chips and the bonding wires.

Shielded radio-frequency (RF) module having reduced area. In some embodiments, an RF module can include a packaging substrate configured to receive a plurality of components, and a plurality of shielding wirebonds implemented on the packaging substrate and configured to provide RF shielding functionality for one or more regions on the packaging substrate. The packaging substrate can include a first area associated with implementation of each shielding wirebond. The RF module can further include one or more devices mounted on the packaging substrate. The packaging substrate can further include a second area associated with mounting of each of the one or more devices. Each device can be mounted with respect to a corresponding shielding wirebond such that the second area associated with the device overlaps at least partially with the first area associated with the corresponding shielding wirebond.

A method for fabricating a semiconductor device includes providing a semiconductor die, arranging an electrical connector over the semiconductor die, the electrical connector including a conductive core, an absorbing feature arranged on a first side of the conductive core, and a solder layer arranged on a second side of the conductive core, opposite the first side and facing the semiconductor die, and soldering the electrical connector onto the semiconductor die by heating the solder layer with a laser, wherein the laser irradiates the absorbing feature and absorbed energy is transferred from the absorbing feature through the conductive core to the solder layer.

A wire comprising a wire core with a surface, the wire core having a coating layer superimposed on its surface, wherein the wire core includes: (a) pure silver consisting of silver and further components; or (b) doped silver consisting of silver, at least one doping element, and further components; or (c) a silver alloy consisting of silver, palladium and further components; or (d) a silver alloy consisting of silver, palladium, gold, and further components; or (e) a doped silver alloy consisting of silver, palladium, gold, at least one doping element, and further components, wherein the individual amount of any further component is less than 30 wt.-ppm and the individual amount of any doping element is at least 30 wt.-ppm, and the coating layer is a single-layer of gold or palladium or a double-layer comprised of an inner layer of nickel or palladium and an adjacent outer layer of gold.

Shielded radio-frequency (RF) module having reduced area. In some embodiments, an RF module can include a packaging substrate configured to receive a plurality of components, and a plurality of shielding wirebonds implemented on the packaging substrate and configured to provide RF shielding functionality for one or more regions on the packaging substrate. The packaging substrate can include a first area associated with implementation of each shielding wirebond. The RF module can further include one or more devices mounted on the packaging substrate. The packaging substrate can further include a second area associated with mounting of each of the one or more devices. Each device can be mounted with respect to a corresponding shielding wirebond such that the second area associated with the device overlaps at least partially with the first area associated with the corresponding shielding wirebond.

A method for fabricating a semiconductor device includes providing a semiconductor die, arranging an electrical connector over the semiconductor die, the electrical connector including a conductive core, an absorbing feature arranged on a first side of the conductive core, and a solder layer arranged on a second side of the conductive core, opposite the first side and facing the semiconductor die, and soldering the electrical connector onto the semiconductor die by heating the solder layer with a laser, wherein the laser irradiates the absorbing feature and absorbed energy is transferred from the absorbing feature through the conductive core to the solder layer.

Shielded radio-frequency (RF) module having reduced area. In some embodiments, a method for fabricating a radio-frequency module includes forming or providing a packaging substrate configured to receive a plurality of components. The method may include mounting one or more devices on the packaging substrate such that the packaging substrate includes a first area associated with mounting of each of the one or more devices. In some embodiments, the method further includes forming a plurality of shielding wirebonds on the packaging substrate to provide RF shielding functionality for one or more regions on the packaging substrate, such that the packaging substrate includes a second area associated with formation of each shielding wirebond, the mounting of each device implemented with respect to a corresponding shielding wirebond such that a portion of the first area associated with the device overlaps at least partially with a portion of the second area associated with the corresponding shielding wirebond.

A wire comprising a wire core with a surface, the wire core having a coating layer superimposed on its surface, wherein the wire core includes: (a) pure silver consisting of silver and further components; or (b) doped silver consisting of silver, at least one doping element, and further components; or (c) a silver alloy consisting of silver, palladium and further components; or (d) a silver alloy consisting of silver, palladium, gold, and further components; or (e) a doped silver alloy consisting of silver, palladium, gold, at least one doping element, and further components, wherein the individual amount of any further component is less than 30 wt.-ppm and the individual amount of any doping element is at least 30 wt.-ppm, and the coating layer is a single-layer of gold or palladium or a double-layer comprised of an inner layer of nickel or palladium and an adjacent outer layer of gold.

There is provided a manufacturing method for a bonded body, comprising: preparing a substrate A having a surface on which a wiring line terminal is provided; forming a polyimide-containing precursor portion on the surface of the substrate A, where the wiring line terminal is provided on the surface of the substrate A; preparing a substrate B having a surface on which a wiring line terminal is provided; and bonding the surface of the substrate A, where the polyimide-containing precursor portion is provided on the surface of the substrate A, to the surface of the substrate B, where the wiring line terminal is provided on the surface of the substrate B, wherein a difference between a cyclization rate of a polyimide in the polyimide-containing precursor portion before the bonding of the surface of the substrate A and a cyclization rate of a polyimide in a polyimide-containing portion formed at a bonded portion after the bonding of the surface of the substrate A is 5% or more.