An integrated circuit package includes a base substrate with at least one electronic chip mounted on a face of the base substrate. The electronic chip is configured to have hot spots in operation emitting heat in a heat volume space. A coating encapsulates the at least one electronic chip. The coating has a bottom face mounted on the face of the base substrate and a profiled top face. A portion of the profile top face is configured to locally reduce a volume of a region of the coating. The portion is located at least in part in the heat volume space. A heat sink is mounted on the profiled top face of the coating using a mounting layer.

A semiconductor package includes electric integrated circuit dies, photoelectric integrated circuit dies, and an inter-chip waveguide. The electric integrated circuit dies are laterally encapsulated by a first insulating encapsulant. The photoelectric integrated circuit dies are laterally encapsulated by a second insulating encapsulant. Each one of photoelectric integrated circuit dies includes an optical input/output terminal. The inter-chip waveguide is disposed over the second insulating encapsulant, wherein the photoelectric integrated circuit dies are optically communicated with each other through the inter-chip waveguide.

A method forming a semiconductor package device includes: providing a substrate; forming a flip chip die on a first side on the substrate; and forming a molding compound on the first side of the substrate. The molding compound covers the flip chip die. The method further includes forming a heat sink on the molding compound; and forming a taping layer on a second side of the substrate, wherein the second side is opposite from the first side in a vertical direction. After forming the taping layer, the method further includes performing a pre-cut process and an etching process on the heat sink; and removing the taping layer.

A chip package structure is disclosed. In one example, the chip package may include a chip, an encapsulation material, and an exposed pad that is electrically conductively connected to the chip. A layer of a porous or dendrite-comprising adhesion promoter is on a surface of the exposed pad. A thermal interface material that is attached to the exposed pad by the layer.

A power converter module includes power transistors and a substrate having a first surface and a second surface that opposes the first surface. A thermal pad is situated on the second surface of the substrate, and the thermal pad is configured to be thermally coupled to a heat sink. The power converter module also includes a control module mounted on a first surface of the substrate. The control module also includes control IC chips coupled to the power transistors. A first control IC chip controls a first switching level of the power converter module and a second control IC chip controls a second switching level of the power converter module. Shielding planes overlay the substrate. A first shielding plane is situated between the thermal pad and the first control IC chip and a second shielding plane is situated between the thermal pad and a second control IC chip.

A semiconductor chip package is provided with improved connections between different components within the package. The semiconductor chip package may comprise a semiconductor chip disposed on a substrate. The semiconductor chip may have a first surface and a second surface. The first surface of the semiconductor chip may be connected to the substrate. The semiconductor chip package may comprise a leadframe that includes a first lead and a second lead. The first lead of the leadframe may be directly attached to the second surface of the semiconductor chip. The second lead of the leadframe may be directly attached to the substrate.

A semiconductor device includes: a semiconductor element; a sealing resin; a gate terminal; a drain terminal; a source terminal; a heat dissipation plate electrically connected to the drain, and protruding from a second side intersecting with a first side of the sealing resin in top view; and a heat dissipation plate electrically connected to the drain, and protruding from a third side opposing the second side of the sealing resin in top view. At least a height position of a lower surface of a distal end portion of the heat dissipation plate and a height position of an upper surface of a proximal end portion of the heat dissipation plate or a height position of a lower surface of a distal end portion of the heat dissipation plate and a height position of an upper surface of a proximal end portion of the heat dissipation plate are the same.

Semiconductor devices including thermally conductive structures are disclosed herein. A heat transfer structure may be thermally coupled to a semiconductor device and directly attached to a signaling layer of a substrate. The heat transfer structure may be configured to remove thermal energy from the semiconductor device and transfer at least a portion of the removed thermal energy directly into the signaling layer for dissipation within the substrate, for transfer through the substrate and out of a corresponding apparatus, or a combination thereof.

This semiconductor device includes: a plate-shaped heat dissipation plate; a plurality of switching elements joined to one surface of the heat dissipation plate; a first terminal located apart from the heat dissipation plate, extending in a direction away from the heat dissipation plate, and connected via first conductors to surfaces of the switching elements on a side opposite to the heat dissipation plate side; and a sealing member sealing the switching elements, the heat dissipation plate, and the first terminal. A cutout is provided at an outer periphery of the heat dissipation plate. A part of the first terminal on the heat dissipation plate side overlaps a cut-out area at the cutout as seen in a direction perpendicular to the one surface of the heat dissipation plate. A retracted portion retracted inward is formed at an outer periphery of another surface of the heat dissipation plate.

This semiconductor device includes: a heat dissipation plate formed in a plate shape; a plurality of switching elements joined to one surface of the heat dissipation plate; a first terminal extending in a direction away from the heat dissipation plate in a state of being apart from the heat dissipation plate, the first terminal being connected via a first electric conductor to surfaces of the plurality of switching elements on an opposite side to the heat dissipation plate side; and a sealing member sealing the plurality of switching elements, the heat dissipation plate, and the first terminal. A notch is provided in an outer periphery portion of the heat dissipation plate. A portion of the first terminal on the heat dissipation plate side overlaps with a region of a cut at the notch as seen in a direction perpendicular to the one surface of the heat dissipation plate.