The present disclosure provides a device die, a die assembly and an electronic system. The device die includes a package and a plurality of transfer pads disposed on a functional surface of the package. The transfer pads are divided into a plurality of segments electrically isolated from each other. In an adjacent pair of transfer pads, there is only one electrical connection between the transfer pads, comprising one segment in one transfer pad electrically connected to one segment in the other transfer pad. The die assembly includes a pair of device dies stacked in a stepped configuration. The electronic system includes a supporting member having at least one metallic layer, and a plurality of device dies disposed on the supporting member and mechanically and electrically coupled to the metallic layer by a plurality of conductive strings.

A package structure including a lead frame structure, a die, an adhesive layer, and at least one three-dimensional (3D) printing conductive wire is provided. The lead frame structure includes a carrier and a lead frame. The carrier has a recess. The lead frame is disposed on the carrier. The die is disposed in the recess. The die includes at least one pad. The adhesive layer is disposed between a bottom surface of the die and the carrier and between a sidewall of the die and the carrier. The 3D printing conductive wire is disposed on the lead frame, the adhesive layer, and the pad, and is electrically connected between the lead frame and the pad.

A package includes a first chip stack. The first chip stack includes a first chip including first bonding structures, a second chip including second bonding structures facing the first bonding structures and bonded to the first bonding structures, and a first electrical contact on the second chip. At least a portion of the first electrical contact does not overlap with the first chip in a plan view.

The present disclosure provides a device die, a die assembly and an electronic system. The device die includes a package and a plurality of transfer pads disposed on a functional surface of the package. The transfer pads are divided into a plurality of segments electrically isolated from each other. In an adjacent pair of transfer pads, there is only one electrical connection between the transfer pads, comprising one segment in one transfer pad electrically connected to one segment in the other transfer pad. The die assembly includes a pair of device dies stacked in a stepped configuration. The electronic system includes a supporting member having at least one metallic layer, and a plurality of device dies disposed on the supporting member and mechanically and electrically coupled to the metallic layer by a plurality of conductive strings.

A semiconductor device includes: a first chip mounting portion; a second chip mounting portion; a first semiconductor chip mounted on the first chip mounting portion; second and third semiconductor chips mounted on the second chip mounting portion; and a sealing body for sealing them. Here, the third semiconductor chip includes a first coil and a second coil that are magnetically coupled to each other. Also, the first coil is electrically connected with a first circuit formed in the first semiconductor chip, and the second coil is electrically connected with a second circuit formed in the second semiconductor chip. Also, in cross-sectional view, the second coil is located closer to the second chip mounting portion than the first coil. Further, a power consumption during an operation of the second semiconductor chip is greater than a power consumption during an operation of the first semiconductor chip.

Provided is a semiconductor integrated circuit device including a plurality of columns of IO cells and having a configuration capable of reducing wiring delays without causing an increase in the area. The semiconductor integrated circuit device includes a first IO cell column group including an IO cell column closest to a periphery of a chip, and a second IO cell column group including an IO cell column adjacent to the first IO cell column group at the side closer to the core region. At least one of the first IO cell column group or the second IO cell column group includes two or more IO cell columns, and the two or more IO cell columns are aligned in the second direction such that the lower power supply voltage regions face each other or the higher power supply voltage regions face each other.

A semiconductor device includes a substrate, a plurality of solders, and a semiconductor chip. The plurality of solders are located adjacent to each other. At least one of composition and concentration of the plurality of solders is different from each other. The semiconductor chip includes a joining surface to be joined to the substrate with the plurality of solders. The joining surface of the semiconductor chip includes a plurality of joining areas in which heat generation of the semiconductor chip or a stress on an object to be joined is different from each other. The plurality of solders are disposed to correspond to the plurality of joining areas, respectively.

A method includes forming a plurality of dielectric layers, forming a plurality of redistribution lines in the plurality of dielectric layers, etching the plurality of dielectric layers to form an opening, filling the opening to form a through-dielectric via penetrating through the plurality of dielectric layers, forming an insulation layer over the through-dielectric via and the plurality of dielectric layers, forming a plurality of bond pads in the dielectric layer, and bonding a device to the insulation layer and a portion of the plurality of bond pads through hybrid bonding.

Provided is a bonding method for directly bonding an electrode part of a chip component to a bonding part provided on a substrate that is a bonding target, the method comprising: a step for placing the substrate on a stage inside a liquid vessel; a step for injecting liquid into the liquid vessel; and a step for bonding the electrode part of the chip component to the bonding part (electrode part) of the bonding target by superimposing the chip component held by a bonding head in the liquid stored in the liquid vessel over the bonding target and then applying pressure thereto.

Semiconductor devices and methods of manufacture are provided wherein a metallization layer is located over a substrate, and a power grid line is located within the metallization layer. A signal pad is located within the metallization layer and the signal pad is surrounded by the power grid line. A signal external connection is electrically connected to the signal pad.