A package includes an integrated circuit. The integrated circuit includes a first chip, a dummy chip, a second chip, and a third chip. The first chip includes a semiconductor substrate that extends continuously from an edge of the first chip to another edge of the first chip. The dummy chip is disposed over the first chip and includes a semiconductor substrate that extends continuously from an edge of the dummy chip to another edge of the dummy chip. Sidewalls of the first chip are aligned with sidewalls of the dummy chip. The second chip and the third chip are sandwiched between the first chip and the dummy chip. A thickness of the second chip is substantially equal to a thickness of the third chip.

A package includes an integrated circuit. The integrated circuit includes a first chip, a dummy chip, a second chip, and a third chip. The first chip includes a semiconductor substrate that extends continuously from an edge of the first chip to another edge of the first chip. The dummy chip is disposed over the first chip and includes a semiconductor substrate that extends continuously from an edge of the dummy chip to another edge of the dummy chip. Sidewalls of the first chip are aligned with sidewalls of the dummy chip. The second chip and the third chip are sandwiched between the first chip and the dummy chip. A thickness of the second chip is substantially equal to a thickness of the third chip.

The semiconductor device includes a substrate including an integrated circuit and a contact that are electrically connected to each other, an insulation layer covering the substrate and including metal lines, and a through electrode electrically connected to the integrated circuit. The insulation layer includes an interlayer dielectric layer on the substrate and an intermetal dielectric layer on the interlayer dielectric layer. The metal lines include a first metal line in the interlayer dielectric layer and electrically connected to the contact, and a plurality of second metal lines in the intermetal dielectric layer and electrically connected to the first metal line and the through electrode. The through electrode includes a top surface higher than a top surface of the contact.

A package structure including an organic interposer substrate, a semiconductor die, conductive bumps, an underfill, and an insulating encapsulation is provided. The organic interposer substrate includes stacked organic dielectric layers and conductive wirings embedded in the stacked organic dielectric layers. The semiconductor die is disposed over and electrically connected to the conductive wirings of the organic interposer substrate, and the semiconductor die includes chamfered edges. The conductive bumps are disposed between the semiconductor die and the organic interposer substrate, and the semiconductor die is electrically connected to the organic interposer substrate through the conductive bumps. The underfill is disposed between the semiconductor die and the organic interposer substrate, wherein the underfill encapsulates the conductive bumps and is in contact with the chamfered edges of the at least one semiconductor die. The insulating encapsulation covers the organic interposer substrate and laterally encapsulates the least one semiconductor die and the underfill.

A package structure including an organic interposer substrate, a semiconductor die, conductive bumps, an underfill, and an insulating encapsulation is provided. The organic interposer substrate includes stacked organic dielectric layers and conductive wirings embedded in the stacked organic dielectric layers. The semiconductor die is disposed over and electrically connected to the conductive wirings of the organic interposer substrate, and the semiconductor die includes chamfered edges. The conductive bumps are disposed between the semiconductor die and the organic interposer substrate, and the semiconductor die is electrically connected to the organic interposer substrate through the conductive bumps. The underfill is disposed between the semiconductor die and the organic interposer substrate, wherein the underfill encapsulates the conductive bumps and is in contact with the chamfered edges of the at least one semiconductor die. The insulating encapsulation covers the organic interposer substrate and laterally encapsulates the least one semiconductor die and the underfill.

A plating chuck for holding a substrate during plating processes, wherein the substrate has a notch area (3031) and a patterned region (3032) adjacent to the notch area (3031). The plating chuck comprises a cover plate (3033) configured to cover the notch area (3031) of the substrate to shield the electric field at the notch area (3031) when the substrate is being plated.

A plating chuck for holding a substrate during plating processes, wherein the substrate has a notch area (3031) and a patterned region (3032) adjacent to the notch area (3031). The plating chuck comprises a cover plate (3033) configured to cover the notch area (3031) of the substrate to shield the electric field at the notch area (3031) when the substrate is being plated.

A semiconductor device manufacturing method including: simultaneously forming a plurality of conductive bumps respectively on a plurality of formation sites by adjusting a forming factor in accordance with an environmental density associated with each formation site; wherein the plurality of conductive bumps including an inter-bump height uniformity smaller than a value, and the environmental density is determined by a number of neighboring formation sites around each formation site in a predetermined range.

A semiconductor device manufacturing method including: simultaneously forming a plurality of conductive bumps respectively on a plurality of formation sites by adjusting a forming factor in accordance with an environmental density associated with each formation site; wherein the plurality of conductive bumps including an inter-bump height uniformity smaller than a value, and the environmental density is determined by a number of neighboring formation sites around each formation site in a predetermined range.

A semiconductor Schottky rectifier built in an epitaxial semiconductor layer over a substrate has an anode structure and a cathode structure extending from the surface of the epitaxial layer. The cathode contact structure has a trench structure near the epi-layer and a vertical sidewall surface covered with a gate oxide layer. The cathode structure further comprises a polysilicon element adjacent to the gate oxide layer.