The present invention provides a semiconductor device. The semiconductor device comprises: a metal pad and a first specific metal layer routing. The metal pad is positioned on a first metal layer of the semiconductor device. The first specific metal layer routing is formed in a second metal layer and directly under the metal pad, wherein an oxide layer is positioned between the first metal layer and the second metal layer.

A semiconductor device may include a metal pad and a first specific metal layer routing. The metal pad is positioned on a first metal layer of the semiconductor device and is directly contacting the first metal layer. The first specific metal layer routing is formed on a second metal layer of the semiconductor device and under the metal pad. In addition, the semiconductor device may include at least one via plug for connecting the first specific metal layer routing to at least one metal region in the first metal layer, where the aforementioned at least one via plug is formed directly under the metal pad.

A semiconductor device capable of inhibiting oxidation of a Cu wiring even in a high temperature operation. The semiconductor device includes a semiconductor substrate having a main surface, a Cu electrode which is selectively formed on a side of the main surface of the semiconductor substrate, an antioxidant film formed on an upper surface of the Cu electrode except an end portion thereof, an organic resin film which is formed on the main surface of the semiconductor substrate and covers a side surface of the Cu electrode and the end portion of the upper surface thereof, and a diffusion prevention film formed between the organic resin film and the main surface of the semiconductor substrate and between the organic resin film and the side surface and the end portion of the upper surface of the Cu electrode, being in contact therewith.

A semiconductor device capable of inhibiting oxidation of a Cu wiring even in a high temperature operation. The semiconductor device includes a semiconductor substrate having a main surface, a Cu electrode which is selectively formed on a side of the main surface of the semiconductor substrate, an antioxidant film formed on an upper surface of the Cu electrode except an end portion thereof, an organic resin film which is formed on the main surface of the semiconductor substrate and covers a side surface of the Cu electrode and the end portion of the upper surface thereof, and a diffusion prevention film formed between the organic resin film and the main surface of the semiconductor substrate and between the organic resin film and the side surface and the end portion of the upper surface of the Cu electrode, being in contact therewith.

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.

A semiconductor device comprises a conductive layer, a first insulating film, a barrier metal, a contact electrode, and a surface electrode. The first insulating film is located on the conductive layer and comprises a contact hole reaching the conductive layer. At least a surface part of the first insulating film is a BPSG film. The barrier metal covers an inner surface of the contact hole. The contact electrode is located in the contact hole and on the barrier metal. The surface electrode is located on the BPSG film and the contact electrode. The barrier metal is not interposed between the BPSG film and the surface electrode so that the surface electrode is directly in contact with the BPSG film. At least a part of the surface electrode is a bonding pad.

The present invention provides a semiconductor device. The semiconductor device comprises: a metal pad and a first specific metal layer routing. The metal pad is positioned on a first metal layer of the semiconductor device. The first specific metal layer routing is formed in a second metal layer and directly under the metal pad, wherein an oxide layer is positioned between the first metal layer and the second metal layer.

A semiconductor device includes a first layer including a number of first layer metal pads, a second layer formed on top of the first layer, the second layer including a number of second layer metal pads, and vias connecting the first layer metal pads to the second layer metal pads. A surface area overlap between the first layer metal pads and the second layer metal pads is below a defined threshold.

A semiconductor device includes a first layer including a number of first layer metal pads, a second layer formed on top of the first layer, the second layer including a number of second layer metal pads, and vias connecting the first layer metal pads to the second layer metal pads. A surface area overlap between the first layer metal pads and the second layer metal pads is below a defined threshold.

The present invention provides a semiconductor device. The semiconductor device comprises: a metal pad and a first specific metal layer routing and a second specific metal layer routing. The metal pad is positioned on a first metal layer of the semiconductor device. The first specific metal layer routing and the second specific metal layer routing are formed in a second metal layer of the semiconductor device, wherein the first specific metal layer routing is directly under the metal pad and the second specific metal layer routing is not directly positioned under the metal pad.