In some examples, a chip scale package (CSP) comprises a semiconductor die; a passivation layer abutting the semiconductor die; a via extending through the passivation layer; and a first metal layer abutting the via. The CSP also includes an insulation layer abutting the first metal layer, with the insulation layer having an orifice with a maximal horizontal area of less than 32400 microns.sup.2. The CSP further includes a second metal layer abutting the insulation layer and adapted to couple to a solder ball. The second metal layer abuts the first metal layer at a point of contact defined by the orifice in the insulation layer.

Semiconductor devices can be formed over a semiconductor substrate, and interconnect-level dielectric material layers embedding metal interconnect structures can be formed thereupon. In one embodiment, a pad-connection-via-level dielectric material layer, a proximal dielectric diffusion barrier layer, and a pad-level dielectric material layer can be formed. Bonding pads surrounded by dielectric diffusion barrier portions can be formed in the pad-level dielectric material layer. In another embodiment, a layer stack of a proximal dielectric diffusion barrier layer and a pad-and-via-level dielectric material layer can be formed. Integrated pad and via cavities can be formed through the pad-and-via-level dielectric material layer, and can be filled with bonding pads containing dielectric diffusion barrier portions and integrated pad and via structures.

Semiconductor devices can be formed over a semiconductor substrate, and interconnect-level dielectric material layers embedding metal interconnect structures can be formed thereupon. In one embodiment, a pad-connection-via-level dielectric material layer, a proximal dielectric diffusion barrier layer, and a pad-level dielectric material layer can be formed. Bonding pads surrounded by dielectric diffusion barrier portions can be formed in the pad-level dielectric material layer. In another embodiment, a layer stack of a proximal dielectric diffusion barrier layer and a pad-and-via-level dielectric material layer can be formed. Integrated pad and via cavities can be formed through the pad-and-via-level dielectric material layer, and can be filled with bonding pads containing dielectric diffusion barrier portions and integrated pad and via structures.

A method of forming a semiconductor device with a metal pillar overlapping a first top metal interconnect and a second top metal interconnect is disclosed. The metal pillar overlapping the first top metal interconnect and second top metal interconnect is connected to the first top metal interconnect by top metal vias while the second top metal interconnect does not contain top metal vias and remains free of a direct electrical connection to the metal pillar. The metal pillars are attached directly to top metal vias without a bond pad of metal. The elimination of the bond pad layer reduces the mask count, processing, and cost of the device. In addition, the elimination of the bond pad results in reduced die area requirements for the metal pillar.

A method of forming a semiconductor device with a metal pillar overlapping a first top metal interconnect and a second top metal interconnect is disclosed. The metal pillar overlapping the first top metal interconnect and second top metal interconnect is connected to the first top metal interconnect by top metal vias while the second top metal interconnect does not contain top metal vias and remains free of a direct electrical connection to the metal pillar. The metal pillars are attached directly to top metal vias without a bond pad of metal. The elimination of the bond pad layer reduces the mask count, processing, and cost of the device. In addition, the elimination of the bond pad results in reduced die area requirements for the metal pillar.

A bonding pad structure and a method thereof includes: a base metal layer formed on a substrate; first conductive vias arranged in a peripheral region of the base metal layer; an intermediate buffer layer formed above the base metal layer, the intermediate buffer layer spaced from and aligned with the base metal layer, the first conductive vias vertically connecting the base metal layer and the intermediate buffer layer; second conductive vias arranged in a peripheral region of the intermediate buffer layer; a surface bonding layer formed above the intermediate buffer layer, the surface bonding layer spaced from and aligned with the intermediate buffer layer, the second conductive vias vertically connecting the intermediate buffer layer and the surface bonding layer, the intermediate buffer layer comprising a mesh structure, and the first conductive vias and the second conductive vias not vertically aligned with a central region of the intermediate buffer layer.

Structures, methods and devices are disclosed, related to improved stack structures in electronic devices. In some embodiments, a stack structure includes a pad implemented on a substrate, the pad including a polymer layer having a side that forms an interface with another layer of the pad, the pad further including an upper metal layer over the interface, the upper metal layer having an upper surface. In some embodiments, the stack structure also includes a passivation layer implemented over the upper metal layer, the passivation layer including a pattern configured to provide a compressive force on the upper metal layer to thereby reduce the likelihood of delamination at the interface, the pattern defining a plurality of openings to expose the upper surface of the upper metal layer.

Structures, methods and devices are disclosed, related to improved stack structures in electronic devices. In some embodiments, a stack structure includes a pad implemented on a substrate, the pad including a polymer layer having a side that forms an interface with another layer of the pad, the pad further including an upper metal layer over the interface, the upper metal layer having an upper surface. In some embodiments, the stack structure also includes a passivation layer implemented over the upper metal layer, the passivation layer including a pattern configured to provide a compressive force on the upper metal layer to thereby reduce the likelihood of delamination at the interface, the pattern defining a plurality of openings to expose the upper surface of the upper metal layer.

Structures, methods and devices are disclosed, related to improved stack structures in electronic devices. In some embodiments, a stack structure includes a pad implemented on a substrate, the pad including a polymer layer having a side that forms an interface with another layer of the pad, the pad further including an upper metal layer over the interface, the upper metal layer having an upper surface. In some embodiments, the stack structure also includes a passivation layer implemented over the upper metal layer, the passivation layer including a pattern configured to provide a compressive force on the upper metal layer to thereby reduce the likelihood of delamination at the interface, the pattern defining a plurality of openings to expose the upper surface of the upper metal layer.

Structures, methods and devices are disclosed, related to improved stack structures in electronic devices. In some embodiments, a stack structure includes a pad implemented on a substrate, the pad including a polymer layer having a side that forms an interface with another layer of the pad, the pad further including an upper metal layer over the interface, the upper metal layer having an upper surface. In some embodiments, the stack structure also includes a passivation layer implemented over the upper metal layer, the passivation layer including a pattern configured to provide a compressive force on the upper metal layer to thereby reduce the likelihood of delamination at the interface, the pattern defining a plurality of openings to expose the upper surface of the upper metal layer.