A semiconductor chip comprises a substrate, a die attach material, and a die. The substrate comprises an upper surface and a lower surface opposing the upper surface. The die attach material is on the upper surface of the substrate. The die comprises a bottom surface bonded to the upper surface of the substrate by the die attach material, a top surface opposing the bottom surface, and a side wall adjacent to the top surface and the bottom surface. A shortest distance across an exterior of the side wall from the bottom surface to the top surface defines an exterior surface distance. The die further comprises a die height measured from where the side wall meets the bottom surface to where the side wall meets the top surface. The exterior surface distance is longer than the die height.

A package structure includes a semiconductor device, a circuit substrate and a heat dissipating lid. The semiconductor device includes a semiconductor die. The circuit substrate is bonded to and electrically coupled to the semiconductor device. The heat dissipating lid is bonded to the circuit substrate and thermally coupled to the semiconductor device, where the semiconductor device is located in a space confined by the heat dissipating lid and the circuit substrate. The heat dissipating lid includes a cover portion and a flange portion bonded to a periphery of the cover portion. The cover portion has a first surface and a second surface opposite to the first surface, where the cover portion includes a recess therein, the recess has an opening at the second surface, and a thickness of the recess is less than a thickness of the cover portion, where the recess is part of the space.

There are provided a semiconductor module capable of preventing the peeling of a sealing resin on the side where a connection section used for the connection to a semiconductor element is arranged and a manufacturing method for a semiconductor module. A semiconductor module includes: an outer frame; sealing resins; gate signal output terminals, and partition sections laid across the outer flame to partition a space into a plurality of housing sections, in the partition sections which the gate signal output terminals with connection sections exposed are arranged. The partition sections have through holes where sealing resins are formed, the sealing resins connecting adjacent housing sections and the sealing resin formed in the through hole being continuous with the sealing resins formed in the housing sections.

There are provided a semiconductor module capable of preventing the peeling of a sealing resin on the side where a connection section used for the connection to a semiconductor element is arranged and a manufacturing method for a semiconductor module. A semiconductor module includes: an outer frame; sealing resins; gate signal output terminals, and partition sections laid across the outer flame to partition a space into a plurality of housing sections, in the partition sections which the gate signal output terminals with connection sections exposed are arranged. The partition sections have through holes where sealing resins are formed, the sealing resins connecting adjacent housing sections and the sealing resin formed in the through hole being continuous with the sealing resins formed in the housing sections.

A semiconductor device includes: a conductive base substrate; a semiconductor chip mounted on the base substrate and having a signal pad; a frame configured to surround the semiconductor chip, to be mounted on the base substrate, and to include a step having an inner first upper surface and an outer second upper surface higher than the first upper surface in a plan view, wherein a first conductor pattern provided on the first upper surface is electrically connected to the base substrate; a capacitive component mounted on the first conductor pattern; a signal terminal mounted on the second upper surface of the frame; a first bonding wire configured to electrically connect the signal pad and an upper surface of the capacitive component; and a second bonding wire configured to electrically connect the upper surface of the capacitive component and the signal terminal.

A bonding structure includes a first layer of first alloy component disposed on a substrate and a first layer of a second alloy component disposed on the first alloy component. The second alloy component has a lower melting temperature than the first alloy component. A second layer of the first alloy component is disposed on the first layer of the second alloy component and a second layer of the second alloy component is disposed on the second layer of the first alloy component.

A bonding structure includes a first layer of first alloy component disposed on a substrate and a first layer of a second alloy component disposed on the first alloy component. The second alloy component has a lower melting temperature than the first alloy component. A second layer of the first alloy component is disposed on the first layer of the second alloy component and a second layer of the second alloy component is disposed on the second layer of the first alloy component.

An integrated circuit package may be formed having at least one heat dissipation structure within the integrated circuit package itself. In one embodiment, the integrated circuit package may include a substrate; at least one integrated circuit device, wherein the at least one integrated circuit device is electrically attached to the substrate; a mold material on the substrate and adjacent to the at least one integrated circuit device; and at least one heat dissipation structure contacting the at least one integrated circuit, wherein the at least one heat dissipation structure is embedded either within the mold material or between the mold material and the substrate.

A power module includes an insulating substrate, a case member, a power semiconductor element, a base member, a sealing member, and an adhesive member. The insulating substrate has a first surface and a second surface opposite to the first surface. The case member surrounds the insulating substrate when viewed in a direction perpendicular to the first surface. The power semiconductor element faces the first surface. The base member faces the second surface. The sealing member seals the power semiconductor element and the insulating substrate and is in contact with the case member. The adhesive member fixes the base member and the case member, and surrounds the insulating substrate when viewed in the direction perpendicular to the first surface.

In one example, an electronic device comprises a cavity substrate comprising a substrate base comprising a top side and a bottom side and a cavity wall over the substrate base and defining a cavity, an electronic component over the substrate base and in the cavity, a lid comprising a top side and a bottom side, wherein the lid is over the substrate base and the cavity wall to define an interior of the cavity and an exterior of the cavity, an adhesive between the bottom side of the lid and a top side of the cavity wall, and a vent seal between the interior of the cavity and the exterior of the cavity. Other examples and related methods are also disclosed herein.