Provided is a package structure including a bottom die, a top die, an insulating layer, a circuit substrate, a dam structure, and an underfill. The top die is bonded on a front side of the bottom die. The insulating layer is disposed on the front side of the bottom die to laterally encapsulate a sidewall of the top die. The circuit substrate is bonded on a back side of the bottom die through a plurality of connectors. The dam structure is disposed between the circuit substrate and the back side of the bottom die, and connected to the back side of the bottom die. The underfill laterally encapsulates the connectors and the dam structure. The dam structure is electrically isolated from the circuit substrate by the underfill. A method of forming the package structure is also provided.

A technique capable of improving a performance of a semiconductor detector is provided. The semiconductor detector is made based on injection of an underfill into a gap between a first semiconductor chip and a second semiconductor chip in a flip-chip connection state, but the underfill is not formed in periphery of a connection structure connecting a reading electrode pad and a gate terminal through a bump electrode.

A method for fabricating a bridge chip assembly for interconnecting two or more IC dies is provided. Each of the IC dies has a first region including first connections having a first pitch and has a second region including second connections or connection pads having a second pitch, the first pitch being greater than the second pitch. The method includes: attaching a non-conductive underfill film on an upper surface of at least the second region of each of the IC dies; bonding the second connections/connection pads of a first IC die to corresponding first connection pads/connections of a bridge chip; and bonding the second connections/connection pads of a second IC die to the bridge chip. The bridge chip assembly includes the bridge chip bonded with the first and second IC dies, and the non-conductive underfill film disposed between the bridge chip and the IC dies.

The semiconductor device includes: a semiconductor element including a body portion formed in a plate shape, a protection film provided at an outer periphery on one surface of the body portion, and a metal thin film provided adjacently to an inner side of the protection film on the one surface of the body portion; a metal member joined to a surface of the metal thin film on a side opposite to the body portion, by solder; and a mold resin sealing the semiconductor element and the metal member, wherein the surface of the metal thin film on the side opposite to the body portion has, on at least a part of an outer periphery thereof, a projection portion projecting from the surface of the metal thin film, and the solder is not provided on an outer peripheral side from a top of the projection portion.

A semiconductor structure includes a semiconductor wafer, a first surface mount component, a second surface mount component and a first barrier structure. The first surface mount component is disposed on the semiconductor wafer, and electrically connected to the semiconductor wafer through a plurality of first electrical connectors. The second surface mount component is disposed on the semiconductor wafer, and electrically connected to the semiconductor wafer through a plurality of second electrical connectors, wherein an edge of the second surface mount component is overhanging a periphery of the semiconductor wafer. The first barrier structure is disposed on the semiconductor wafer in between the second electrical connectors and the edge of the second surface mount component, wherein a first surface of the first barrier structure is facing the second electrical connectors, and a second surface of the first barrier structure is facing away from the second electrical connectors.

A semiconductor package includes a circuit board mounting a first semiconductor chip and a second semiconductor chip laterally separated by an intermediate space, an underfill including an extended portion protruding upward into the intermediate space, a surface modification layer on opposing side surfaces of the first semiconductor chip and the second semiconductor chip, wherein wettability of the underfill with respect to the surface modification layer is less than wettability of the underfill with respect to the side surfaces of the first semiconductor chip and the second semiconductor chip, and a molding member on the upper surface of the circuit board, covering an upper surface of the extended portion of the underfill, and surrounding the first semiconductor chip and the second semiconductor chip.

A method for forming a chip package structure is provided. The method includes disposing a chip package over a wiring substrate. The method includes forming a first heat conductive structure and a second heat conductive structure over the chip package. The first heat conductive structure and the second heat conductive structure are separated by a first gap. The method includes bonding a heat dissipation lid to the chip package through the first heat conductive structure and the second heat conductive structure. The first heat conductive structure and the second heat conductive structure extend toward each other until the first heat conductive structure contacts the second heat conductive structure during bonding the heat dissipation lid to the chip package.

A method for producing a semiconductor arrangement includes applying a metallization layer on an upper main side of a lower semiconductor chip, structuring the metallization layer, and fastening an upper semiconductor chip on the upper main side of the lower semiconductor chip by a bonding material, wherein the metallization layer is structured such that the metallization layer has an increased roughness along a contour of the upper semiconductor chip in comparison with the rest of the metallization layer, wherein wetting of the upper main side of the lower semiconductor chip by the bonding material is limited by a structure in the metallization layer to a region below the upper semiconductor chip.

A semiconductor device having a capillary flow structure for a direct chip attachment is provided herein. The semiconductor device generally includes a substrate and a semiconductor die having a conductive pillar electrically coupled to the substrate. The front side of the semiconductor die may be spaced a distance apart from the substrate forming a gap. The semiconductor device further includes first and second elongate capillary flow structures projecting from the front side of the semiconductor die at least partially extending toward the substrate. The first and second elongate capillary flow structures may be spaced apart from each other at a first width configured to induce capillary flow of an underfill material along a length of the first and second elongate capillary flow structures. The first and second capillary flow structures may include pairs of elongate capillary flow structures forming passageways therebetween to induce capillary flow at an increased flow rate.

An exemplary semiconductor device can comprise (a) a substrate comprising a substrate dielectric structure between the substrate top side and the substrate bottom side, conductive pads at the substrate bottom side, and a substrate cavity through the substrate dielectric structure, (b) a base electronic component comprising inner short bumps; outer short bumps bounding a perimeter around the inner short bumps, and tall bumps between the outer short bumps and an edge of the base component top side, and (c) a mounted electronic component coupled to the inner short bumps of the base electronic component. The tall bumps of the base component can be coupled to the conductive pads of the substrate. The mounted electronic component can be located in the substrate cavity. The substrate bottom side can cover at least a portion of the outer short bumps of the base electronic component. Other examples and related methods are disclosed herein.