A clip for a semiconductor package. Implementations may include: an electrically conductive clip having a first end and a second end and a middle section between the first end and the second end. The first end may be configured to couple to a first die through a bonding material. The second end may be configured to couple to a second die through a bonding material. The middle section may be configured to couple to an emitter structure through a bonding material. The clip may include an integrally formed electrically conductive material and include an M-shape. A middle of the M-shape may be coupled to the emitter structure.

In one embodiment, methods for making semiconductor devices are disclosed.

According to an aspect, a power electronic module includes a substrate, a semiconductor die coupled to the substrate, and a clip member configured to secure the semiconductor die to the substrate, where the clip member includes a base portion having a surface coupled to the semiconductor die, an extender portion that extends from the base portion, where the extender portion includes a contact portion coupled to the substrate, and at least one protrusion that extends from the base portion or the extender portion.

The semiconductor device includes a semiconductor element, and an electro-conductive first plate-like part electrically connected to a top-face-side electrode of the semiconductor element and including a first joint part projecting from a side face, and an electro-conductive second plate-like part including a second joint part projecting from a side face. A bottom face of the first joint part and a top face of the second joint part face one another, and are electrically connected via an electro-conductive bonding material. A bonding-material-thickness ensuring means is provided in a zone where the bottom face of the first joint part and the top face of the second joint part face one another to ensure a thickness of the electro-conductive bonding material between an upper portion of a front end of the second joint part and the bottom face of the first joint part.

A semiconductor module can be realized, which is formed by mounting an electronic component and a bus bar by solder on a lead frame including a plurality of terminals, wherein a solder flow suppressing section capable of restricting a direction of flow of solder on the lead frame is formed in the vicinity of the solder portion of the component mounted by solder, and by this configuration, positional deviation, such as rotation or movement of the mounted component, is suppressed and the size of the module can be made compact.

According to an aspect, a power electronic module includes a substrate, a semiconductor die coupled to the substrate, and a clip member configured to secure the semiconductor die to the substrate, where the clip member includes a base portion having a surface coupled to the semiconductor die, an extender portion that extends from the base portion, where the extender portion includes a contact portion coupled to the substrate, and at least one protrusion that extends from the base portion or the extender portion.

The device has a first support element forming a first thermal dissipation surface and carrying a first power component; a second support element forming a second thermal dissipation surface and carrying a second power component, a first contacting element superimposed to the first power component; a second contacting element superimposed to the second power component; a plurality of leads electrically coupled with the power components through the first and/or the second support elements; and a thermally conductive body arranged between the first and the second contacting elements. The first and the second support elements and the first and the second contacting elements are formed by electrically insulating and thermally conductive multilayers.