Provided is a semiconductor package including: at least one semiconductor device on a first substrate; a non-conductive film (NCF) on the at least one semiconductor device and comprising an irreversible thermochromic pigment; and a molding member on the at least one semiconductor device in a lateral direction, wherein a content of the irreversible thermochromic pigment in the NCF is about 0.1 wt % to about 5 wt % with respect to a weight of the NCF.

A semiconductor package includes a base chip and at least one semiconductor chip disposed on the base chip. An adhesive film is disposed between the base chip and the at least one semiconductor chip and is configured to fix the at least one semiconductor chip on the base chip. The adhesive film includes an inner film portion that overlaps the at least one semiconductor chip in a thickness direction of the base chip, and an outer film portion that does not overlap the at least one semiconductor chip in the thickness direction of the base chip. A width of the outer film portion in a direction perpendicular to a lateral edge of the at least one semiconductor chip is substantially uniform within a deviation range of 20% of an average width of the outer film portion.

In described examples, a circuit (e.g., an integrated circuit) includes a semiconductor substrate that includes a frontside surface and a backside surface. A circuit element is included at the frontside surface. An optional electrical insulator layer can be included adjacent to the backside surface. A distributor layer is included adjacent to the backside surface. In some examples, the distributor layer includes a distributor material that includes a matrix of cohered nanoparticles and metallic particles embedded by the cohered nanoparticles.

A device manufacturing method includes: applying a bonding material in a predetermined position on a mounting face of a base by dispensing the bonding material through a nozzle of a bonding machine, in which an outline of a leading end face of the nozzle defines an area of at least 75% of a bonding face of a component to be mounted, so that the bonding material applied onto the mounting face has an outline that at least partially extends beyond a shape of the bonding face; and bonding the bonding face in the predetermined position on the mounting face by placing and pressing the component onto the base via the bonding material so that at least a portion of the bonding material interposed between the mounting face of the base and the bonding face of the component flows out beyond the bonding face of the component.

A device manufacturing method includes: applying a bonding material in a predetermined position on a mounting face of a base by dispensing the bonding material through a nozzle of a bonding machine, in which an outline of a leading end face of the nozzle defines an area of at least 75% of a bonding face of a component to be mounted, so that the bonding material applied onto the mounting face has an outline that at least partially extends beyond a shape of the bonding face; and bonding the bonding face in the predetermined position on the mounting face by placing and pressing the component onto the base via the bonding material so that at least a portion of the bonding material interposed between the mounting face of the base and the bonding face of the component flows out beyond the bonding face of the component.

A semiconductor structure includes a substrate component, an IC die component over the substrate component, and a composite redistribution structure interposed between and electrically coupled to the substrate and IC die components. The composite redistribution structure includes a local interconnect component between a first redistribution structure overlying the substrate component and a second redistribution structure underlying the IC die component, and an insulating encapsulation between the first and second redistribution structures and embedding the local interconnect component therein. The local interconnect component includes TSVs penetrating through a substrate and electrically coupled to first and second conductive connectors, the first conductive connectors between the first redistribution structure and a first side of the substrate, the second conductive connectors between the second redistribution structure and a second side of the substrate, and a first insulating layer between the first redistribution structure and the first side and laterally covering the first conductive connectors.

A bonded body is provided including: a bonding layer containing Cu; and a semiconductor element bonded to the bonding layer. The bonding layer includes an extending portion laterally extending from a peripheral edge of the semiconductor element. In a cross-sectional view in a thickness direction, the extending portion rises from a peripheral edge of a bottom of the semiconductor element or from the vicinity of the peripheral edge of the bottom of the semiconductor element, and includes a side wall substantially spaced apart from a side of the semiconductor element. Preferably, the extending portion does not include any portion where the side wall and the side of the semiconductor element are in contact with each other. A method for manufacturing a bonded body is also provided.

A bonded body is provided including: a bonding layer containing Cu; and a semiconductor element bonded to the bonding layer. The bonding layer includes an extending portion laterally extending from a peripheral edge of the semiconductor element. In a cross-sectional view in a thickness direction, the extending portion rises from a peripheral edge of a bottom of the semiconductor element or from the vicinity of the peripheral edge of the bottom of the semiconductor element, and includes a side wall substantially spaced apart from a side of the semiconductor element. Preferably, the extending portion does not include any portion where the side wall and the side of the semiconductor element are in contact with each other. A method for manufacturing a bonded body is also provided.

A semiconductor package includes a substrate, a plurality of semiconductor devices stacked on the substrate, a plurality of underfill fillets disposed between the plurality of semiconductor devices and between the substrate and the plurality of semiconductor devices, and molding resin surrounding the plurality of semiconductor devices. At least one of the underfill fillets is exposed from side surfaces of the molding resin.

Provided is a package structure including a photonic die, an electronic die, a conductive layer, a circuit substrate, and an underfill. The electronic die is bonded on a front side of the photonic die. The conductive layer is disposed on a back side of the photonic die. The conductive layer includes a plurality of conductive pads and a dam structure between the conductive pads and a first sidewall of the photonic die. The circuit substrate is bonded on the back side of the photonic die through a plurality of connectors and the conductive pads. The underfill laterally encapsulates the connectors, the conductive pads, and the dam structure. The underfill at the first sidewall of the photonic die has a first height, the underfill at a second sidewall of the photonic die has a second height, and the first height is lower than the second height.