Embodiments of molded packages and corresponding methods of manufacture are provided. In an embodiment of a molded package, the molded package includes a laser-activatable mold compound having a plurality of laser-activated regions which are plated with an electrically conductive material to form metal pads and/or metal traces at a first side of the laser-activatable mold compound. A semiconductor die embedded in the laser-activatable mold compound has a plurality of die pads. An interconnect electrically connects the plurality of die pads of the semiconductor die to the metal pads and/or metal traces at the first side of the laser-activatable mold compound.

The present disclosure relates to a mold module that includes a device layer, a number of first bump structures, a first mold compound, a stop layer, and a second mold compound. The device layer includes a number of input/output (I/O) contacts at a top surface of the device layer. Each first bump structure is formed over the device layer and electronically coupled to a corresponding I/O contact. The first mold compound resides over the device layer, and a portion of each first bump structure is exposed through the first mold compound. The stop layer is formed underneath the device layer. The second mold compound resides underneath the stop layer, such that the stop layer separates the device layer from the second mold compound.

The present invention relates to a structure for packaging and the method for manufacturing the same. The structure for packaging comprise two or more metal members disposed on a substrate or a semiconductor device. A patterned layer and an insulation layer are disposed surrounding the metal members. There is a gap between the patterned layer and the insulation layer. Thereby, while bonding the metal members, metal spilling can be avoided, for further preventing the structure from short circuit or current leakage.

A multi-chip package includes a package substrate including a first substrate pad, a first group of semiconductor chips stacked on the package substrate, each of the first group of the semiconductor chips including bonding pads, first stud bumps arranged on the bonding pads of the first group of the semiconductor chips except for a lowermost semiconductor chip in the first group, a first conductive wire downwardly extended from the bonding pad of the lowermost semiconductor chip in the first group and connected to the first substrate pad, and a second conductive wire upwardly extended from the bonding pad of the lowermost semiconductor chip in the first group and sequentially connected to the first stud bumps.

A semiconductor device includes a first semiconductor die package. The first semiconductor package includes a molding compound, and a conductive element in the molding compound, wherein a top surface of the conductive element is above or co-planar with a top-most surface of the molding compound. The semiconductor device further includes a second semiconductor die package The second semiconductor package includes a plurality of copper-containing contacts on a single metal pad, wherein each of the plurality of copper-containing contacts is bonded to the conductive element.

A method of making a semiconductor device comprising the steps of providing a first manufacturing line, providing a second manufacturing line, and forming a first redistribution interconnect structure using the first manufacturing line while forming a second redistribution interconnect structure using the second manufacturing line. The method further includes the steps of testing a first unit of the first redistribution interconnect structure to determine a first known good unit (KGU), disposing a known good semiconductor die (KGD) over the first KGU of the first redistribution interconnect structure, and dicing the first KGU and KGD from the first redistribution interconnect structure. The method further includes the steps of testing a unit of the second redistribution interconnect structure to determine a second KGU of the second redistribution interconnect structure and disposing first KGU of the first redistribution interconnect structure and the KGD over the second KGU of the second redistribution interconnect structure.

A process for molding a back side wafer singulation guide is disclosed. Structures for heat mitigation include an overmold formed over a contact surface of a device layer of a wafer, covering bump structures. The overmold and bump structures are thinned and planarized, and the overmold provides an underfill to increase interconnect reliability of a semiconductor die in a flip chip bonded package. However, visibility of singulation guides on the contact surface is obstructed. A channel is formed extending through the device layer and into the handle layer, and is filled with the overmold. The handle layer is replaced with a thermally-conductive molding layer formed on the back side for dissipating heat generated by semiconductor devices. The thermally-conductive handle is thinned until the overmold in the channel beneath the device layer is exposed. The exposed overmold provides a visible back side singulation guide for singulating the wafer.

Embodiments include an electronic system and methods of forming an electronic system. In an embodiment, the electronic system may include a package substrate and a die coupled to the package substrate. In an embodiment, the electronic system may also include an integrated heat spreader (IHS) that is coupled to the package substrate. In an embodiment the electronic system may further comprise a thermal interface pad between the IHS and the die. In an embodiment the die is thermally coupled to the IHS by a liquid metal thermal interface material (TIM) that contacts the thermal interface pad.

A method of producing an optoelectronic component includes providing an optoelectronic semiconductor chip having a first surface on which a first electrical contact and a second electrical contact are arranged; arranging a protection diode on the first contact and the second contact; galvanically growing a first pin on the first electrical contact and a second pin on the second electrical contact; and embedding the first pin, the second pin, and the protection diode in a molded body.

A method of producing an optoelectronic component includes providing an optoelectronic semiconductor chip having a first surface on which a first electrical contact and a second electrical contact are arranged; arranging a protection diode on the first contact and the second contact; galvanically growing a first pin on the first electrical contact and a second pin on the second electrical contact; and embedding the first pin, the second pin, and the protection diode in a molded body.