A method for separating integrated circuit dies from a wafer includes making at least two cutting passes with a laser along a first die street of an integrated circuit die, the first die street extending along a first axis on the wafer. The method also includes making at least two cutting passes with the laser along a second die street of the integrated circuit die, the second die street extending along a second axis on the wafer that is generally perpendicular to the first axis. In one process, three cutting passes are made with the laser alternatingly along the first and second die streets to separate the integrated die circuit along the first and second axes. In another process, two cutting passes are made with the laser along the first die street in opposite directions, and two cutting passes are then made with the laser along the second die street in opposite directions.

A method for separating integrated circuit dies from a wafer includes making at least two cutting passes with a laser along a first die street of an integrated circuit die, the first die street extending along a first axis on the wafer. The method also includes making at least two cutting passes with the laser along a second die street of the integrated circuit die, the second die street extending along a second axis on the wafer that is generally perpendicular to the first axis. In one process, three cutting passes are made with the laser alternatingly along the first and second die streets to separate the integrated die circuit along the first and second axes. In another process, two cutting passes are made with the laser along the first die street in opposite directions, and two cutting passes are then made with the laser along the second die street in opposite directions.

A semiconductor integrated circuit device includes a core region and an IO region on a chip. In an IO cell row placed in the IO region, a first power supply line extending in the X direction in a low power supply voltage region has a portion protruding to the core region. A signal IO cell has a reinforcing line that connects a second power supply line extending in the X direction in the low power supply voltage region and a third power supply line extending in the X direction in a high power supply voltage region, the reinforcing line extending in the Y direction in a layer above the second and third power supply lines.

Various embodiments of fanout packages are disclosed. A method of forming a microelectronic assembly is disclosed. The method can include bonding a first surface of at least one microelectronic substrate to a surface of a carrier using a direct bonding technique without an intervening adhesive, the microelectronic substrate having a plurality of conductive interconnections on at least one surface of the microelectronic substrate. The method can include applying a molding material to an area of the surface of the carrier surrounding the microelectronic substrate to form a reconstituted substrate. The method can include processing the microelectronic substrate. The method can include singulating the reconstituted substrate at the area of the surface of the carrier and at the molding material to form the microelectronic assembly.

Various embodiments of fanout packages are disclosed. A method of forming a microelectronic assembly is disclosed. The method can include bonding a first surface of at least one microelectronic substrate to a surface of a carrier using a direct bonding technique without an intervening adhesive, the microelectronic substrate having a plurality of conductive interconnections on at least one surface of the microelectronic substrate. The method can include applying a molding material to an area of the surface of the carrier surrounding the microelectronic substrate to form a reconstituted substrate. The method can include processing the microelectronic substrate. The method can include singulating the reconstituted substrate at the area of the surface of the carrier and at the molding material to form the microelectronic assembly.

A method and an apparatus for bonding semiconductor substrates are provided. The apparatus includes a first support configured to carry a first semiconductor substrate and a second semiconductor substrate bonded to each other, a gauging component embedded in the first support and comprising a fiducial pattern, and a first sensor disposed proximate to the gauging component, and configured to emit a light source towards the fiducial pattern of the gauging component.

A semiconductor device package includes a substrate, a partition structure and a polymer film. The partition structure is disposed on the substrate and defines a space for accommodating a semiconductor device. The polymer film is adjacent to a side of the partition structure distal to the substrate. A first side surface of the polymer film substantially aligns with a first side surface of the partition structure.

A semiconductor device package includes a substrate, a partition structure and a polymer film. The partition structure is disposed on the substrate and defines a space for accommodating a semiconductor device. The polymer film is adjacent to a side of the partition structure distal to the substrate. A first side surface of the polymer film substantially aligns with a first side surface of the partition structure.

A composite integrated circuit (IC) device structure comprising a host chip and a chiplet. The host chip comprises a first device layer and a first metallization layer. The chiplet comprises a second device layer and a second metallization layer that is interconnected to transistors of the second device layer. A top metallization layer comprising a plurality of first level interconnect (FLI) interfaces is over the chiplet and host chip. The chiplet is embedded between a first region of the first device layer and the top metallization layer. The first region of the first device layer is interconnected to the top metallization layer by one or more conductive vias extending through the second device layer or adjacent to an edge sidewall of the chiplet.

A composite integrated circuit (IC) device structure comprising a host chip and a chiplet. The host chip comprises a first device layer and a first metallization layer. The chiplet comprises a second device layer and a second metallization layer that is interconnected to transistors of the second device layer. A top metallization layer comprising a plurality of first level interconnect (FLI) interfaces is over the chiplet and host chip. The chiplet is embedded between a first region of the first device layer and the top metallization layer. The first region of the first device layer is interconnected to the top metallization layer by one or more conductive vias extending through the second device layer or adjacent to an edge sidewall of the chiplet.