A semiconductor device package may include a leadframe having a first portion with first extended portions and a second portion with second extended portions. Mold material may encapsulate a portion of the leadframe and a portion of a semiconductor die mounted to the leadframe. A first set of contacts of the semiconductor die may be connected to a first surface of the first extended portions, while a second set of contacts may be connected to a first surface of the second extended portions. A mold-locking cavity having the mold material included therein may be disposed in contact with a second surface of the first extended portions opposed to the first surface of the first extended portions, a second surface of the second extended portions opposed to the first surface of the second extended portions, the first portion of the leadframe, and the second portion of the leadframe.

An apparatus is provided which comprises: a substrate, a die site on the substrate to couple with a die, a die side component site on the substrate to couple with a die side component, and a raised barrier on the substrate between the die and die side component sites to contain underfill material disposed at the die site, wherein the raised barrier comprises electroplated metal. Other embodiments are also disclosed and claimed.

An electronic device includes: a support member that has a metallic placement surface joined to the conductive bonding layer, and a metallic sealing surface provided on an outer side of the placement surface in an in-plane direction of the placement surface to adjoin the placement surface and to surround the placement surface; and a resin member, which is a synthetic resin molded article, joined to the sealing surface and covering the electronic component. The sealing surface includes a rough surface having a plurality of laser irradiation marks having a substantially circular shape. The rough surface includes a first region and a second region. The second region has a higher density of the laser irradiation marks in the in-plane direction than the first region.

A device comprising a connecting plate and a circuit element is disclosed. The circuit element is electrically coupled to the connecting plate through a solder connection including a plurality of solder balls disposed between the circuit element and the connecting plate. An underfill layer is formed between the circuit element and the connecting plate and configured to provide bonding between the circuit element and the connecting plate. The solder connection includes a first solder area with a first solder ball density and a second solder area with a second solder ball density. The first solder ball density is less than the second solder ball density. The underfill layer includes a bonding material continuously disposed in the second solder area of the solder connection.

A device comprising a connecting plate and a circuit element is disclosed. The circuit element is electrically coupled to the connecting plate through a solder connection including a plurality of solder balls disposed between the circuit element and the connecting plate. An underfill layer is formed between the circuit element and the connecting plate and configured to provide bonding between the circuit element and the connecting plate. The solder connection includes a first solder area with a first solder ball density and a second solder area with a second solder ball density. The first solder ball density is less than the second solder ball density. The underfill layer includes a bonding material continuously disposed in the second solder area of the solder connection.

An apparatus is provided which comprises: a substrate, a die site on the substrate to couple with a die, a die side component site on the substrate to couple with a die side component, and a raised barrier on the substrate between the die and die side component sites to contain underfill material disposed at the die site, wherein the raised barrier comprises electroplated metal. Other embodiments are also disclosed and claimed.

A package structure including a first die, an encapsulant, a first circuit structure, a second circuit structure, a conductive connector, a second die, and a filler is provided. The encapsulant covers the first die and has a first surface and a second surface opposite to each other. The first circuit structure is disposed on the first surface. The second circuit structure is disposed on the second surface. The conductive connector penetrates the encapsulant. The second die is disposed on the second circuit structure. The second die has an optical signal transmission area. The filler is disposed between the second die and the second circuit structure. An upper surface of the second circuit structure has a groove. The upper surface includes a first area and a second area disposed on opposite sides of the groove. The filler directly contacts the first area. The filler is disposed away from the second area.

A package includes a package substrate, the package substrate having a first side and a second side opposite to the first side, a package component bonded to the first side of the package substrate, a front-side warpage control structure attached to the first side of the package substrate, and a backside warpage control structure embedded in the package substrate from the second side of the package substrate. The front-side warpage control structure includes a first disconnected structure and a second disconnected structure laterally separated from each other by a gap. The backside warpage control structure includes a third disconnected structure and a fourth disconnected structure laterally separated from each other.

A semiconductor package is disclosed. The disclosed semiconductor package includes a substrate having bonding pads at an upper surface thereof, a lower semiconductor chip, at least one upper semiconductor chip disposed on the lower semiconductor chip, and a dam structure having a closed loop shape surrounding the lower semiconductor chip. The dam structure includes narrow and wide dams disposed between the lower semiconductor chip and the bonding pads. The wide dam has a greater inner width than the narrow dam. The semiconductor packages further includes an underfill disposed inside the dam structure and being filled between the substrate and the lower semiconductor chip.

A package structure including a first die, an encapsulant, a first circuit structure, a second circuit structure, a conductive connector, a second die, and a filler is provided. The encapsulant covers the first die and has a first surface and a second surface opposite to each other. The first circuit structure is disposed on the first surface. The second circuit structure is disposed on the second surface. The conductive connector penetrates the encapsulant. The second die is disposed on the second circuit structure. The second die has an optical signal transmission area. The filler is disposed between the second die and the second circuit structure. An upper surface of the second circuit structure has a groove. The upper surface includes a first area and a second area disposed on opposite sides of the groove. The filler directly contacts the first area. The filler is disposed away from the second area.