A semiconductor package may include a package substrate, semiconductor chips, signal bumps, and first and second heat dissipation bumps. The semiconductor chips may be stacked on an upper surface of the package substrate, have first and second regions having different heat dissipation efficiencies. The second temperature may be higher than the first temperature. The signal bumps may be arranged between the semiconductor chips. The first heat dissipation bumps may be arranged between the semiconductor chips in the first region by a first pitch. The second heat dissipation bumps may be arranged between the semiconductor chips in the second region by a second pitch narrower than the first pitch. Heat generated from the second region of the semiconductor chips may be dissipated through the second heat dissipation bumps, which may be relatively closely arranged with each other.

Semiconductor assemblies including thermal layers and associated systems and methods are disclosed herein. In some embodiments, the semiconductor assemblies comprise one or more semiconductor devices over a substrate. The substrate includes a thermal layer configured to transfer thermal energy along a lateral plane and across the substrate. The thermal energy is transferred along a non-lateral direction from the semiconductor device to the graphene layer using one or more thermal connectors.

A method of manufacturing a semiconductor device having a conductive substrate having a first surface, a second surface opposite the first surface, and a passivation material covering a portion of the first surface can include applying a seed layer of conductive material to the first surface of the conductive substrate and to the passivation material, the seed layer having a first face opposite the conductive substrate. The method can include forming a plurality of pillars comprising layers of first and second materials. The method can include etching the seed layer to undercut the seed layer between the conductive substrate and the first material of at least one of the pillars. In some embodiments, a cross-sectional area of the seed layer in contact with the passivation material between the first material and the conductive substrate is less than the cross-sectional area of the second material.

A semiconductor package includes an interposer including first and second surfaces opposite to each other. The semiconductor package also includes a heat dissipation layer disposed on the first surface of the interposer and a first semiconductor die mounted on the first surface of the interposer. The semiconductor package additionally includes a stack of second semiconductor dies mounted on the second surface of the interposer. The semiconductor package further includes a thermally conductive connection part for transferring heat from the stack of the second semiconductor dies to the heat dissipation layer.

Disclosed is a semiconductor device such as a power amplifier. Unlike conventional power amplifiers, thermal bump is patterned to only cover active devices. In this way, dimensions of the semiconductor device can be reduced.

To provide a semiconductor device and a semiconductor module that are capable of improving a heat dissipation property in the semiconductor device including a heat generating element. A semiconductor device includes: a P-type semiconductor substrate, which has a main surface and a main surface opposed to the main surface; an N-type N well, which is provided on the main surface side of the semiconductor substrate; a unit field effect transistor, which is provided in the N well; a P-type heat dissipation guard ring region, which is provided on the main surface side of the semiconductor substrate on the outside of the N well in plan view of the semiconductor substrate; wiring, which is provided on the heat dissipation guard ring region; bump placement portions; and bumps.

The disclosure concerns an electronic device and methods of making an electronic device. The electronic device includes a circuit that is at least partially formed in an active region of a substrate. An electronic package is stacked on the substrate. A via extends through the circuit from the active region of the substrate to a surface of the substrate that is opposite the active region. At least one contacting element connects the via to the electronic package.

3D integrated circuit (3DIC) device architecture is disclosed for monolithically heterogeneous integration of III-V devices over Si-CMOS devices with high-quality (HQ) integrated passives devices (IPD) or re-distributed layers (RDL). In addition, a thermal spreader may be added over the upper III-V tier to enhance device power performance (e.g., PAE for PA) and device reliability (e.g., with a reduced Tj/junction temperature).

Disclosed is a semiconductor package with increased thermal radiation efficiency, which includes: a first die having signal and dummy regions and including first vias in the signal region, a second die on the first die and including second vias in the signal region, first die pads on a top surface of the first die and coupled to the first vias, first connection terminals on the first die pads which couple the second vias to the first vias, second die pads in the dummy region and on the top surface of the first die, and second connection terminals on the second die pads and electrically insulated from the first vias and the second vias. Each of the second die pads has a rectangular planar shape whose major axis is provided along a direction that leads away from the signal region.

The disclosure concerns an electronic device and methods of making an electronic device. The electronic device includes a circuit that is at least partially formed in an active region of a substrate. An electronic package is stacked on the substrate. A via extends through the circuit from the active region of the substrate to a surface of the substrate that is opposite the active region. At least one contacting element connects the via to the electronic package.