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.

A power semiconductor module includes a substrate with a metallization layer and a power semiconductor chip bonded to the metallization layer of the substrate. A metallic plate has a first surface bonded to a surface of the power semiconductor chip opposite to the substrate. The metallic plate has a central part and a border that are both bonded to the power semiconductor chip. The border of the metallic plate is structured in such a way that the metallic plate has less metal material per volume at the border as compared to the central part of the metallic plate. Metallic interconnection elements are bonded to a second surface of the metallic plate at the central part.

A semiconductor device is provided. The semiconductor device includes an electric field (E-field) suppression layer formed over a termination region. The E-field suppression layer is patterned with openings over metal contact areas. The E-field suppression layer has a thickness such that an electric field strength above the E-field suppression layer is below a dielectric strength of an adjacent material when the semiconductor device is operating at or below a maximum voltage.

In a described example, an apparatus includes: a package substrate including a die pad configured for mounting a semiconductor die, a first lead connected to the die pad, and a second lead and a third lead; and a semiconductor die including a temperature sensor mounted on the die pad. The semiconductor die includes a first metallization layer being a metallization layer closest to the active surface of the semiconductor die, and successive metallization layers overlying the previous metallization layer, the metallization layers including a respective conductor layer in a dielectric material for the particular metallization layer and conductive vias; and the temperature sensor formed of the conductor layer in an uppermost metallization layer and coupled to the second lead and to the third lead. The semiconductor die includes a high voltage ring formed in the uppermost metallization layer, spaced from and surrounding the temperature sensor.

A semiconductor device includes an insulation substrate including a circuit pattern, semiconductor chips mounted on the circuit pattern, a wire connecting between the semiconductor chips and between the semiconductor chip and the circuit pattern, and a conductive material serving as a conductor formed integrally with the wire.

A technique for marking semiconductor devices with an identifiable mark or alphanumeric text yields a high-contrast, easily distinguishable mark on an electrical terminal of the device without impacting the device's breakdown voltage capability and without compromising the solderability and wire bondability of the terminal. This approach deposits the mark on the terminal as a patterned layer of palladium, which offers good contrast with the base metal of the terminal and maintains the solderability and bondability of the terminal.

A semiconductor device is provided, which includes a semiconductor chip; a first current input/output portion that is electrically connected to the semiconductor chip; a second current input/output portion that is electrically connected to the semiconductor chip; three or more conducting portions provided with the semiconductor chip, between the first current input/output portion and the second current input/output portion; and a current path portion having a path through which current is conducted to each of the three or more conducting portions, wherein the current path portion includes a plurality of slits.

A semiconductor device is provided, which includes a semiconductor chip; a first current input/output portion that is electrically connected to the semiconductor chip; a second current input/output portion that is electrically connected to the semiconductor chip; three or more conducting portions provided with the semiconductor chip, between the first current input/output portion and the second current input/output portion; and a current path portion having a path through which current is conducted to each of the three or more conducting portions, wherein the current path portion includes a plurality of slits.

A semiconductor device includes a chip that includes a mounting surface, a non-mounting surface, and a side wall connecting the mounting surface and the non-mounting surface and has an eaves portion protruding further outward than the mounting surface at the side wall and a metal layer that covers the mounting surface.

A device includes an interposer including an insulative layer between a lower metal layer and a first upper metal layer and a second upper metal layer, a semiconductor transistor die attached to the first upper metal layer and comprising a first lower main face and a second upper main face, with a drain or collector pad on the first main face and electrically connected to the first upper metal layer, a source or emitter electrode pad and a gate electrode pad on the second main face, a leadframe connected to the interposer and comprising a first lead connected with the first upper metal layer, a second lead connected with the source electrode pad, and a third lead connected with the second upper metal layer, and wherein an electrical connector that is connected between the gate electrode pad and the second upper metal layer is orthogonal to a first electrical connector.