In a semiconductor device according to the present disclosure, one end and the other end of a plurality of insulation covering wires are joined to a connection region in an upper electrode of a DBC substrate over a semiconductor element while an insulation covering portion in a center region has contact with a surface of the semiconductor element. The plurality of insulation covering wires are provided along an X direction in the same manner as the plurality of metal wires. The plurality of insulation covering wires are provided with no loosening, thus have press force of pressing the semiconductor element in a direction of the solder joint portion.

A semiconductor package assembly and method of manufacturing is provided. The assembly includes a semiconductor package and a moulding resin case encapsulating the semiconductor package. The package includes a lead frame having a first frame side and a second frame side opposite to the first frame side; a silicon die structure having a first die side and a second die side opposite to the first side, the silicon die structure being mounted with its second die side on the first frame side of the lead frame; one or more bond wires electrically connecting the silicon die structure with the lead frame; as well as a coating layer covering the semiconductor package from the encapsulating moulding resin case, the coating layer being composed of two or more different amorphous layer coatings. The use of a coating layer covering the complete semiconductor package forming the encapsulating moulding resin case prevents any corrosion.

A semiconductor package assembly and method of manufacturing is provided. The assembly includes a semiconductor package and a moulding resin case encapsulating the semiconductor package. The package includes a lead frame having a first frame side and a second frame side opposite to the first frame side; a silicon die structure having a first die side and a second die side opposite to the first side, the silicon die structure being mounted with its second die side on the first frame side of the lead frame; one or more bond wires electrically connecting the silicon die structure with the lead frame; as well as a coating layer covering the semiconductor package from the encapsulating moulding resin case, the coating layer being composed of two or more different amorphous layer coatings. The use of a coating layer covering the complete semiconductor package forming the encapsulating moulding resin case prevents any corrosion.

The present invention provides a bonding wire capable of simultaneously satisfying ball bonding reliability and wedge bondability required of bonding wires for memories, the bonding wire including a core material containing one or more of Ga, In, and Sn for a total of 0.1 to 3.0 at % with a balance being made up of Ag and incidental impurities; and a coating layer formed over a surface of the core material, containing one or more of Pd and Pt, or Ag and one or more of Pd and Pt, with a balance being made up of incidental impurities, wherein the coating layer is 0.005 to 0.070 μm in thickness.

The present invention provides a bonding wire capable of simultaneously satisfying ball bonding reliability and wedge bondability required of bonding wires for memories, the bonding wire including a core material containing one or more of Ga, In, and Sn for a total of 0.1 to 3.0 at % with a balance being made up of Ag and incidental impurities; and a coating layer formed over a surface of the core material, containing one or more of Pd and Pt, or Ag and one or more of Pd and Pt, with a balance being made up of incidental impurities, wherein the coating layer is 0.005 to 0.070 μm in thickness.

In various embodiments, a chip package is provided. The chip package may include a chip, a metal contact structure including a non-noble metal and electrically contacting the chip, a packaging material, and a protective layer including or essentially consisting of a portion formed at an interface between a portion of the metal contact structure and the packaging material, wherein the protective layer may include a noble metal, wherein the portion of the protective layer may include a plurality of regions free from the noble metal, and wherein the regions free from the noble metal may provide an interface between the packaging material and the non-noble metal of the metal contact structure.

In various embodiments, a chip package is provided. The chip package may include a chip, a metal contact structure including a non-noble metal and electrically contacting the chip, a packaging material, and a protective layer including or essentially consisting of a portion formed at an interface between a portion of the metal contact structure and the packaging material, wherein the protective layer may include a noble metal, wherein the portion of the protective layer may include a plurality of regions free from the noble metal, and wherein the regions free from the noble metal may provide an interface between the packaging material and the non-noble metal of the metal contact structure.

In various embodiments, a chip package is provided. The chip package may include a chip including a chip metal surface, a metal contact structure electrically contacting the chip metal surface, and packaging material including a contact layer being in physical contact with the chip metal surface and/or with the metal contact structure; wherein at least in the contact layer of the packaging material, a summed concentration of chemically reactive sulfur, chemically reactive selenium and chemically reactive tellurium is less than 10 atomic parts per million.

In various embodiments, a chip package is provided. The chip package may include a chip including a chip metal surface, a metal contact structure electrically contacting the chip metal surface, and packaging material including a contact layer being in physical contact with the chip metal surface and/or with the metal contact structure; wherein at least in the contact layer of the packaging material, a summed concentration of chemically reactive sulfur, chemically reactive selenium and chemically reactive tellurium is less than 10 atomic parts per million.

Embodiments of the present invention are directed to a method of manufacturing a semiconductor package with an internal routing circuit. The internal routing circuit is formed from multiple molding routing layers in a plated and etched copper terminal semiconductor package by using an inkjet process to create conductive paths on each molding compound layer of the semiconductor package.