An integrated circuit device including a semiconductor substrate, a first bonding pad structure, a second bonding pad structure, a third bonding pad structure, a first internal bonding wire, and a second internal bonding wire is provided. The first bonding pad structure is disposed on a surface of the semiconductor substrate and exposed outside of the semiconductor substrate. The second bonding pad structure is disposed on the surface of the semiconductor substrate and exposed outside of the semiconductor substrate. The third bonding pad structure is disposed on the surface of the semiconductor substrate and exposed outside of the semiconductor substrate. The first bonding pad structure is electrically coupled to the third bonding pad structure via the first internal bonding wire. The third bonding pad structure is electrically coupled to the second bonding pad structure via the second internal bonding wire.

A semiconductor device includes a silicon substrate, a first layer, a second layer, a barrier metal, and a gate pad. The first layer is formed of an oxide film provided on an upper surface of the silicon substrate. The second layer is a layer at least selectively having a projecting and recessed part on an upper surface of the first layer, the projecting and recessed part having a projection and recess deeper than a projection and recess occurring when the layer is formed in a planar shape. The barrier metal is formed on an upper surface of the second layer according to a shape of the projecting and recessed part. The gate pad is in close contact with the silicon substrate via the barrier metal.

A conductive terminal on an integrated circuit is provided. The conductive terminal includes a conductive pad, a dielectric layer, and a conductive via. The conductive pad is disposed on and electrically to the integrated circuit. The dielectric layer covers the integrated circuit and the conductive pad, the dielectric layer includes a plurality of contact openings arranged in array, and the conductive pad is partially exposed by the contact openings. The conductive via is disposed on the dielectric layer and electrically connected to the conductive pad through the contact openings. The conductive via includes a plurality of convex portions arranged in array. The convex portions are distributed on a top surface of the conductive via, and the convex portions are corresponding to the contact openings.

The present disclosure provides a semiconductor structure. The semiconductor structure comprises a semiconductive substrate and an interconnect structure over the semiconductive substrate. The semiconductor structure also comprises a bond pad in the semiconductive substrate and coupled to the metal layer. The bond pad comprises two conductive layers.

A bonding pad structure comprises a first dielectric layer, a first conductive island in a second dielectric layer over the first dielectric layer and a via array having a plurality of vias in a third dielectric layer over the first conductive island. The structure also comprises a plurality of second conductive islands in a fourth dielectric layer over the via array. The second conductive islands are each separated from one another by a dielectric material of the fourth dielectric layer and in contact with at least one via of the via array. The structure further comprises a substrate over the second conductive islands. The substrate has an opening defined therein that exposes at least one second conductive island. The structure additionally comprises a bonding pad over the substrate. The bonding pad is in contact with the at least one second conductive island through the opening in the substrate.

The present disclosure provides a semiconductor structure. The semiconductor structure comprises a semiconductive substrate and an interconnect structure over the semiconductive substrate. The semiconductor structure also comprises a bond pad in the semiconductive substrate and coupled to the metal layer. The bond pad comprises two conductive layers.

An integrated circuit device including a semiconductor substrate, a first bonding pad structure, a second bonding pad structure, a third bonding pad structure, a first internal bonding wire, and a second internal bonding wire is provided. The first bonding pad structure is disposed on a surface of the semiconductor substrate and exposed outside of the semiconductor substrate. The second bonding pad structure is disposed on the surface of the semiconductor substrate and exposed outside of the semiconductor substrate. The third bonding pad structure is disposed on the surface of the semiconductor substrate and exposed outside of the semiconductor substrate. The first bonding pad structure is electrically coupled to the third bonding pad structure via the first internal bonding wire. The third bonding pad structure is electrically coupled to the second bonding pad structure via the second internal bonding wire.

A semiconductor device includes a carrier and a metallic structure including a metallic member, a pad and a via portion; wherein the metallic member is disposed inside the carrier, the pad is configured for receiving a solder bump and is disposed on a surface of the carrier, the via portion is configured for electrically connecting the metallic member and the pad, and the via portion is disposed proximal to an end of the pad. Further, a method of manufacturing a semiconductor device includes providing a carrier, removing a portion of the carrier for forming a via extending a surface of the carrier to an interior of the carrier, filling the via by a conductive material, and disposing the conductive material on the surface of the carrier, wherein the via is disposed proximal to an end portion of the conductive material.

An integrated circuit device including a semiconductor substrate, a first bonding pad structure, a second bonding pad structure, and an internal bonding wire is provided. The first bonding pad structure is disposed on a surface of the semiconductor substrate and exposed outside of the semiconductor substrate. The second bonding pad structure is disposed on the surface of the semiconductor substrate and exposed outside of the semiconductor substrate. The first bonding pad structure is electrically coupled to the second bonding pad structure via the internal bonding wire. The integrated circuit device having a better electrical performance is provided by eliminating internal resistance drop in power supply trails or ground trails, and improving signal integrity of the integrated circuit device.

Technologies for thermal plugs in photonic integrated circuit (PIC) dies are disclosed. In an illustrative embodiment, several thermal plugs extend from contact pads in a PIC die, through a dielectric layer, to a waveguide layer. The thermal plugs can carry heat at a higher rate than the surrounding dielectric layer, increasing the heat transfer through the PIC die. The PIC die may be mounted on an electronic integrated circuit (EIC) die in an integrated circuit component. The PIC die can transfer heat from the EIC die, through the PIC die, and to another component such as an integrated heat spreader, lowering the temperature of the EIC die. The thermal plugs can increase the heat transfer through the PIC die.