Metal-free frame designs for silicon bridges for semiconductor packages and the resulting silicon bridges and semiconductor packages are described. In an example, a semiconductor structure includes a substrate having an insulating layer disposed thereon, the substrate having a perimeter. A metallization structure is disposed on the insulating layer, the metallization structure including conductive routing disposed in a dielectric material stack. A first metal guard ring is disposed in the dielectric material stack and surrounds the conductive routing. A second metal guard ring is disposed in the dielectric material stack and surrounds the first metal guard ring. A metal-free region of the dielectric material stack surrounds the second metal guard ring. The metal-free region is disposed adjacent to the second metal guard ring and adjacent to the perimeter of the substrate.

Integrated circuit packages with multiple integrated circuit dies are provided. A multichip package may include at least two integrated circuit dies that communicate using an embedded multi-die interconnect bridge (EMIB) in a substrate of the multi-chip package. The EMIB may receive power at contact pads formed at a back side of the EMIB that are coupled to a back side conductor on which the EMIB is mounted. The back side conductor may be separated into multiple regions that are electrically isolated from one another and that each receive a different power supply voltage signal or data signal from a printed circuit board. These power supply voltage signals and data signals may be provided to the two integrated circuit dies through internal microvias or through-silicon vias formed in the EMIB.

Hyperchip structures and methods of fabricating hyperchips are described. In an example, an integrated circuit assembly includes a first integrated circuit chip having a device side opposite a backside. The device side includes a plurality of transistor devices and a plurality of device side contact points. The backside includes a plurality of backside contacts. A second integrated circuit chip includes a device side having a plurality of device contact points thereon. The second integrated circuit chip is on the first integrated circuit chip in a device side to device side configuration. Ones of the plurality of device contact points of the second integrated circuit chip are coupled to ones of the plurality of device contact points of the first integrated circuit chip. The second integrated circuit chip is smaller than the first integrated circuit chip from a plan view perspective.

Methods/structures of joining package structures are described. Those methods/structures may include a die disposed on a surface of a substrate, an interconnect bridge embedded in the substrate, and at least one vertical interconnect structure disposed through a portion of the interconnect bridge, wherein the at least one vertical interconnect structure is electrically and physically coupled to the die.

A power module includes at least two power units. Each power unit includes at least one power semiconductor and a substrate. In order to reduce the installation space required for the power module and to improve cooling, the at least one power semiconductor is connected, in particular in a materially bonded manner, to the substrate. The substrates of the at least two power units are each directly connected in a materially bonded manner to a surface of a common heat sink. A power converter having at least one power module is also disclosed.

Embodiments include semiconductor packages and a method to form such semiconductor packages. A semiconductor package includes a plurality of dies on a substrate, and an encapsulation layer over the substrate. The encapsulation layer surrounds the dies. The semiconductor package also includes a plurality of dummy silicon regions on the substrate. The dummy silicon regions surround the dies and encapsulation layer. The plurality of dummy silicon regions are positioned on two or more edges of the substrate. The dummy silicon regions have a top surface substantially coplanar to a top surface of the dies. The dummy silicon regions include materials that include silicon, metals, or highly-thermal conductive materials. The materials have a thermal conductivity of approximately 120 W/mK or greater, or is equal to or greater than the thermal conductivity of silicon. An underfill layer surrounds the substrate and the dies, where the encapsulation layer surrounds portions of the underfill layer.

A method for manufacturing a semiconductor package may include: forming a photoimageable dielectric layer on a substrate including a pad; forming a preliminary via hole in the photoimageable dielectric layer to expose the pad; forming a hard mask layer on the photoimageable dielectric layer and the pad; etching the photoimageable dielectric layer and the hard mask layer to form a via hole, a first hole, and a trench; forming a metal layer on the photoimageable dielectric layer connected to the pad; planarizing the metal layer to form a wiring pattern; and placing a semiconductor chip electrically connected to the wiring pattern. The first hole may be disposed on the via hole and connected thereto, and a diameter of the first hole may be larger than a diameter of the via hole.

A semiconductor chip includes a front surface and a back surface, a source pad, a drain pad and a gate pad on the front surface; a die pad under the semiconductor chip and bonded to the semiconductor chip; a source lead, electrically connected to the die pad; a drain lead and a gate lead, disposed on a periphery of the die pad; and a sealing resin. A plurality of vias for external connection are formed to connect to the source pad. A first subset of the plurality of vias for external connection is disposed along a first side of the source pad, and a second subset of the plurality of vias for external connection is disposed along a second side of the source pad, wherein the first and second sides are arranged adjacent to each other to form a first edge of the source pad.

Provided is a semiconductor package and a method of manufacturing the same, wherein in the semiconductor package, an area on a surface of a heat release metal layer pressed by a molding die is expanded and the molding die directly and uniformly compresses an upper substrate and/or a lower substrate, each of which does not include heat release posts so that contamination of a substrate occurring due to a molding resin may be prevented and molding may be stably performed.

A circuit structure is provided. The circuit structure may include a first die area including an output gate, a second die area including a circuit and an input gate and a die-to-die interconnect. The input gate may include a transistor. The circuit may be connected between the die-to-die interconnect and a gate region of the transistor. The circuit may include a MOS transistor. A first source/drain region of the MOS transistor may be connected to the die-to-die interconnect.