To divide a semiconductor wafer by stealth dicing, a test pad in a cutting region and an alignment target are collectively arranged along one side in a width direction of the cutting region, and a laser beam for forming a modified region is irradiated to a position away in plane from the test pad and the alignment target Am. In this manner, defects in cutting shape in a cutting process of a semiconductor wafer using stealth dicing can be reduced or prevented.

A hybrid bonded structure including a first integrated circuit component and a second integrated circuit component is provided. The first integrated circuit component includes a first dielectric layer, first conductors and isolation structures. The first conductors and the isolation structures are embedded in the first dielectric layer. The isolation structures are electrically insulated from the first conductors and surround the first conductors. The second integrated circuit component includes a second dielectric layer and second conductors. The second conductors are embedded in the second dielectric layer. The first dielectric layer is bonded to the second dielectric layer and the first conductors are bonded to the second conductors.

Some implementations described herein provide techniques and apparatuses for forming a stacked die product including two or more integrated circuit dies. A bond interface between two integrated circuit dies that are included in the stacked die product includes a layered structure. As part of the layered structure, respective layers of a sealant material are directly on co-facing surfaces of the two integrated circuit dies. The layered structure further includes one or more bonding layers between the respective layers of the sealant material that are directly on the co-facing surfaces of the two integrated circuit dies. The layered structure may reduce lateral stresses throughout the bond interface to reduce a likelihood of warpage of the two integrated circuit dies.

A method is provided. The method includes providing a first wafer having a plurality of first dummy pads exposed along a first surface of the first wafer. The first dummy pads contact a first metallization layer of the first water. The method also includes providing a second wafer having a plurality of second dummy pads exposed along a first surface of the second wafer. The second dummy pads contact a second metallization layer of the second wafer. The method also includes bonding the first wafer to the second wafer in a manner that the first surface of the first wafer contacts the first surface of the second wafer and the plurality of first dummy pads are interleaved with the plurality of second dummy pads but do not contact the plurality of second dummy pads.

A semiconductor device includes a semiconductor element, a lead on which the semiconductor element is mounted, a bonding member fixing the semiconductor element to the lead, and a resin package enclosing the semiconductor element and a portion of the lead. This lead is formed with a groove recessed at a location spaced from the semiconductor element. The groove has first and second inner surfaces, where the first inner surface is closer to the semiconductor element than is the second inner surface. The angle the first inner surface forms with respect to the thickness direction of the semiconductor element is smaller than the angle the second inner surface forms with respect to the thickness direction.

A semiconductor device comprises a semiconductor chip which includes at least one gate structure on a substrate, the gate structure including a first region, a second region different from the first region, and a third region between the first and the second region, a first redistribution layer on a top surface of the semiconductor chip, the first redistribution layer configured to electrically connect a first electrode pad of the semiconductor chip to a first solder ball and overlap the first region of the gate structure, a second redistribution layer on the top surface of the semiconductor chip, the second redistribution layer configured to electrically connect a second electrode pad of the semiconductor chip to a second solder ball and overlap the second region of the gate structure such that the third region is exposed, and an insulating layer on the first redistribution layer and the second redistribution layer.

To divide a semiconductor wafer by stealth dicing, a test pad in a cutting region and an alignment target are collectively arranged along one side in a width direction of the cutting region, and a laser beam for forming a modified region is irradiated to a position away in plane from the test pad and the alignment target Am. In this manner, defects in cutting shape in a cutting process of a semiconductor wafer using stealth dicing can be reduced or prevented.

Semiconductor devices and methods of manufacture thereof are disclosed. In some embodiments, a semiconductor device includes a substrate, and a plurality of contact pads disposed over the substrate. The contact pads may be arranged in a ball grid array (BGA), and the may include a plurality of corners. A metal dam is disposed around each of the plurality of corners, such as corners of the BGA.

A fan-out wafer level package structure includes a chip, a molding compound, at least one circuit layer, and at least one dielectric layer. The molding compound encapsulates the chip. The at least one circuit layer is disposed on a surface of the chip and a surface of the molding compound coplanar to the surface of the chip. The at least one circuit layer includes a plurality of traces. Each of the traces includes a first portion and a second portion. The first portion is located at an edge region of a projection of the chip onto the dielectric layer. A width of the first portion is larger than a width of the second portion. The at least one dielectric layer is disposed at a side of the at least one circuit layer.

The present application is applicable to the field of semiconductor technology and provides a method for packaging stacking a flip chip, which includes: placing a filling template on a substrate, the filling template being provided with a through hole of a preset pattern; filling a filling material into the through hole of the filling template, and after the filling material being formed on the substrate, removing the filling template; placing a chip with solder balls on the substrate formed with the filling material, such that at least a portion of the solder balls being covered by the filling material; and connecting the chip to the substrate through the solder balls, and curing the filling material with air gaps formed between the at least a portion of the solder balls covered with the filling material.