A semiconductor device has a module structure in which a semiconductor element and a circuit layer are electrically connected to each other by a wire. A front metal layer is formed on a surface of a top side electrode of the semiconductor element and the wire is bonded to the front metal layer by wire bonding. The front metal layer has a higher hardness than the top side electrode or the wire. A bonding interface of the wire with the metal film has a recrystallization temperature that is equal to or higher than 175° C. According to this structure, it is possible to improve the power cycle resistance of the semiconductor device.

A process for electrically connecting contact surfaces of electronic components by capillary wedge bonding a round wire of 8 to 80 μm to the contact surface of a first electronic component, forming a wire loop, and stitch bonding the wire to the contact surface of a second electronic component, wherein the wire comprises a wire core having a silver or silver-based wire core with a double-layered coating comprised of a 1 to 50 nm thick inner layer of nickel or palladium and an adjacent 5 to 200 nm thick outer layer of gold.

A process for electrically connecting contact surfaces of electronic components by capillary wedge bonding a round wire of 8 to 80 μm to the contact surface of a first electronic component, forming a wire loop, and stitch bonding the wire to the contact surface of a second electronic component, wherein the wire comprises a wire core having a silver or silver-based wire core with a double-layered coating comprised of a 1 to 50 nm thick inner layer of nickel or palladium and an adjacent 5 to 200 nm thick outer layer of gold.

A device includes a first semiconductor chip that is arranged over a first carrier and includes a first electrical contact. The device further includes a second semiconductor chip arranged over a second carrier and including a second electrical contact arranged over a surface of the second semiconductor chip facing the second carrier. The second carrier is electrically coupled to the first electrical contact and the second electrical contact.

A device includes a first semiconductor chip that is arranged over a first carrier and includes a first electrical contact. The device further includes a second semiconductor chip arranged over a second carrier and including a second electrical contact arranged over a surface of the second semiconductor chip facing the second carrier. The second carrier is electrically coupled to the first electrical contact and the second electrical contact.

A semiconductor lead frame includes a metal plate and a semiconductor chip mounting area provided on a top surface of the metal plate. A first plating layer for an internal terminal is provided around the semiconductor chip mounting area. A second plating layer for an external terminal is provided on a back surface of the metal plate at a location opposite to the semiconductor chip mounting area. The first plating layer includes a fall-off prevention structure for preventing the first plating layer from falling off from an encapsulating resin when the top surface of the metal plate is encapsulated in the encapsulating resin. The second plating layer does not include the fall-off prevention structure.

A semiconductor lead frame includes a metal plate and a semiconductor chip mounting area provided on a top surface of the metal plate. A first plating layer for an internal terminal is provided around the semiconductor chip mounting area. A second plating layer for an external terminal is provided on a back surface of the metal plate at a location opposite to the semiconductor chip mounting area. The first plating layer includes a fall-off prevention structure for preventing the first plating layer from falling off from an encapsulating resin when the top surface of the metal plate is encapsulated in the encapsulating resin. The second plating layer does not include the fall-off prevention structure.

The present disclosure provides a semiconductor device. The semiconductor device includes a semiconductor chip having a first main surface including an active region and a peripheral region surrounding the active region; a first trench formed in the active region; a first insulating film formed on an inner surface of the first trench; a first electrode formed in the first trench interfacing the first insulating film, and forming a channel in a portion of the semiconductor chip facing the first insulating film; a second trench formed in the peripheral region and having a width greater a width of the first trench; a second insulating film formed on an inner surface of the second trench; and a second electrode formed in the second trench interfacing the second insulating film and electrically coupled to the first electrode.

The present disclosure provides a semiconductor device. The semiconductor device includes a semiconductor chip having a first main surface including an active region and a peripheral region surrounding the active region; a first trench formed in the active region; a first insulating film formed on an inner surface of the first trench; a first electrode formed in the first trench interfacing the first insulating film, and forming a channel in a portion of the semiconductor chip facing the first insulating film; a second trench formed in the peripheral region and having a width greater a width of the first trench; a second insulating film formed on an inner surface of the second trench; and a second electrode formed in the second trench interfacing the second insulating film and electrically coupled to the first electrode.

A transistor amplifier package includes a base, one or more transistor dies on the base, first and second leads coupled to the one or more transistor dies and defining respective radio frequency (RF) signal paths, and an isolation structure on the base between the respective RF signal paths. The isolation structure includes first and second wire bonds. The first and second wire bonds may have a crossed configuration defining at least one cross point therebetween. Related wire bond-based isolation structures are also discussed.