The present invention provides a semiconductor device for reducing parasitic inductance. The semiconductor device of the present invention includes: a semiconductor chip, including a front surface and a hack surface, and including a source pad, a drain pad and a gate pad on the front surface; a die pad, disposed under the semiconductor chip and bonded to the hack surface of the semiconductor chip; a source lead, electrically connected to the die pad; a drain lead and a gate lead, disposed on a periphery of the die pad; and a sealing resin, sealing the semiconductor chip, the die pad and each of the leads. At least one via for external connection is formed in the semiconductor chip to connect to the source pad, and the via for external connection is disposed on a circumferential portion of the semiconductor chip in perspective view.

The present invention provides a packaging method and a packaging structure for a cascode power electronic device, in which a hetero-multiple chip scale package is used to replace the traditional die bonding and wire bonding packaging method. The cascode power electronic device can reduce the inductance resistance and thermal resistance of the connecting wires and reduce the size of the package; and increase the switching frequency of power density. The chip scale package of the present invention uses more than one gallium nitride semiconductor die, more than one diode, and more than one metal oxide semiconductor transistor. The package structure can use TO-220, quad flat package or other shapes and sizes; the encapsulation process of the traditional epoxy molding compounds can be used in low-power applications; and the encapsulation process of ceramic material can be used in high-power applications.

A method of manufacturing a cascode HEMT semiconductor device including a lead frame, a die pad with an indentation attached to the lead frame, and a HEMT die attached to the die pad. The HEMT die includes a HEMT source and a HEMT drain on a first side, and a HEMT gate on a second side. The device further includes a MOSFET die attached to the source of the HEMT die, and the MOSFET die includes a MOSFET source, a MOSFET gate and a MOSFET drain. The MOSFET drain is connected to the HEMT source, and the MOSFET source includes a MOSFET source clip. The MOSFET source clip includes a pillar so to connect the MOSFET source to the HEMT gate, and the connection between the MOSFET source to the HEMT gate is established by a conductive material.

The present disclosure is directed to the stacking of semiconductor structures, such as dies, and the stacked semiconductor assembly is suitable to be directly mounted to a Printed Circuit Board, PCB. The present disclosure allows for a small sized stacked semiconductor assembly utilizing both the MOSFET and the HEMT in a single assembly.

A method of forming a semiconductor device includes providing a carrier comprising a die attach pad, providing a semiconductor die that includes a bond pad disposed on a main surface of the semiconductor die, and providing a metal interconnect element, arranging the semiconductor die on the die attach pad such that the bond pad faces away from the die attach pad, and welding the metal interconnect element to the bond pad, wherein the bond pad comprises first and second metal layers, wherein the second metal layer is disposed between the first metal layer and a semiconductor body of the semiconductor die, wherein a thickness of the first metal layer is greater than a thickness of the second metal layer, and wherein the first metal layer has a different metal composition as the second metal layer.

Embodiments of this application provide a semiconductor structure, an electronic device, and a manufacture method for a semiconductor structure, and relate to the field of heat dissipation technologies for electronic products. An example semiconductor structure includes a semiconductor device, a bonding layer, a substrate, a conducting via, and a metal layer. The semiconductor device is disposed on an upper surface of the substrate by using the bonding layer. The metal layer is disposed on a lower surface of the substrate. The substrate includes a base plate, a groove formed on the base plate, and a diamond accommodated in the groove. The conducting via penetrates the substrate, the bonding layer, and at least a part of the semiconductor device, and is electrically connected to the metal layer. The groove bypasses the conducting via.

A semiconductor device according to one embodiment includes: a semiconductor chip having a transistor and a drain pad provided on a board; a capacitor having an upper electrode and a lower electrode interposing a dielectric; a pad; and an empty pad provided on the board of the semiconductor chip. The semiconductor device further includes: a first wire connecting the pad and the drain pad of the semiconductor chip to each other; a second wire connecting the empty pad and the upper electrode of the capacitor to each other; and a third wire connecting the pad and the empty pad to each other.

Disclosed is a package for a semiconductor device including a semiconductor die. The package includes a base member, a side wall, first and second conductive films, and first and second conductive leads. The base member has a conductive main surface including a region that mounts the semiconductor die. The side wall surrounds the region and is made of a dielectric. The side wall includes first and second portions. The first and second conductive films are provided on the first and second portions, respectively and are electrically connected to the semiconductor die. The first and second conductive leads are conductively bonded to the first and second conductive films, respectively. At least one of the first and second portions includes a recess in its back surface facing the base member, and the recess defines a gap between the at least one of the first and second portions below the corresponding conductive film and the base member.

A semiconductor device includes a conductive member including first, second and third conductors mutually spaced, a first semiconductor element having a first obverse surface provided with a first drain electrode, a first source electrode and a first gate electrode, and a second semiconductor element having a second obverse surface provided with a second drain electrode, a second source electrode and a second gate electrode. The first conductor is electrically connected to the first source electrode and the second drain electrode. The second conductor is electrically connected to the second source electrode. As viewed in a first direction crossing the first obverse surface, the second conductor is adjacent to the first conductor in a second direction crossing the first direction. The third conductor is electrically connected to the first drain electrode and is adjacent to the first conductor and the second conductor as viewed in the first direction.

A circuit element is formed on a substrate made of a compound semiconductor. A bonding pad is disposed on the circuit element so as to at least partially overlap the circuit element. The bonding pad includes a first metal film and a second metal film formed on the first metal film. A metal material of the second metal film has a higher Young's modulus than a metal material of the first metal film.