A method of forming semiconductor device includes forming interconnect structure over substrate; forming first passivation layer over the interconnect structure, and metal-insulator-metal capacitor in the first passivation layer; forming first redistribution layer including first pads over the first passivation layer, and first vias extending into the first passivation layer; conformally forming second passivation layer over the first redistribution layer and first passivation layer, and patterning the second passivation layer to form via openings exposing the first pads; forming second redistribution layer including second pads over the second passivation layer, and second vias in the first via openings, wherein the first and second redistribution layers include aluminum-copper alloy and copper, respectively; forming dielectric layer over the second redistribution layer, and patterning the dielectric layer to form via openings exposing some second pads; and forming bumps over the dielectric layer and in the via openings to contact exposed second pads.

A semiconductor package includes a substrate portion including a core layer having a device accommodating portion formed therein, and a buildup layer stacked on each of opposing sides of the core layer; an electronic device disposed in the device accommodating portion; and heat dissipating conductors disposed in the buildup layer to externally emit heat generated by the electronic device.

A memory device including a memory cell array region, includes, column selection signal lines formed in a first column conduction layer of the memory cell array region and extending in a column direction, global input-output data lines formed in a second column conduction layer of the memory cell array region different from the first column conduction layer and extending in the column direction and power lines formed in a shield conduction layer of the memory cell array region between the first column conduction layer and the second column conduction layer. The noises in the signal lines and the power lines may be reduced and performance of the memory device may be enhanced by forming the column selection signal lines and the global input-output data lines in different column conduction layers and forming the power lines in the shield conduction layer between the column conduction layers.

In some examples, a semiconductor package comprises a semiconductor die including circuitry, a first metal pillar coupled to the circuitry and extending away from the semiconductor die, and a second metal pillar coupled to the circuitry and extending away from the semiconductor die. A distance between the first and second metal pillars does not exceed 100 microns. The package also comprises a polyimide layer covering portions of the first and second metal pillars and covering a region between the first and second metal pillars. The polyimide layer in the region between the first and second metal pillars has a thickness not exceeding 15 microns and lacks a boundary between separate applications of polyimide to the region. The package also includes a mold compound covering the polyimide layer in the region between the first and second metal pillars. The package further includes conductive terminals coupled to the first and second metal pillars and exposed to an exterior of the mold compound.

A semiconductor package includes a substrate portion including a core layer having a device accommodating portion formed therein, and a buildup layer stacked on each of opposing sides of the core layer; an electronic device disposed in the device accommodating portion; and heat dissipating conductors disposed in the buildup layer to externally emit heat generated by the electronic device.

A memory device including a memory cell array region, includes, column selection signal lines formed in a first column conduction layer of the memory cell array region and extending in a column direction, global input-output data lines formed in a second column conduction layer of the memory cell array region different from the first column conduction layer and extending in the column direction and power lines formed in a shield conduction layer of the memory cell array region between the first column conduction layer and the second column conduction layer. The noises in the signal lines and the power lines may be reduced and performance of the memory device may be enhanced by forming the column selection signal lines and the global input-output data lines in different column conduction layers and forming the power lines in the shield conduction layer between the column conduction layers.

Semiconductor devices with redistribution pads are disclosed. The semiconductor device includes a plurality of electric pads provided on a semiconductor substrate, and a plurality of redistribution pads electrically connected to the electric pads and an outer terminal. The plurality of redistribution pads includes a plurality of first redistribution pads constituting a transmission path for a first electrical signal and at least one second redistribution pad constituting a transmission path for a second electrical signal different from the first electrical signal. The first redistribution pads are arranged on the semiconductor substrate to form at least two rows, and the at least one second redistribution pad is disposed between the at least two rows of the first redistribution pads.

Semiconductor devices with redistribution pads are disclosed. The semiconductor device includes a plurality of electric pads provided on a semiconductor substrate, and a plurality of redistribution pads electrically connected to the electric pads and an outer terminal. The plurality of redistribution pads includes a plurality of first redistribution pads constituting a transmission path for a first electrical signal and at least one second redistribution pad constituting a transmission path for a second electrical signal different from the first electrical signal. The first redistribution pads are arranged on the semiconductor substrate to form at least two rows, and the at least one second redistribution pad is disposed between the at least two rows of the first redistribution pads.