A semiconductor device includes a header, a semiconductor chip fixed to the header constituting a MOSFET, and a sealing body of insulating resin which covers the semiconductor chip, the header and the like, and further includes a drain lead contiguously formed with the header and projects from one side surface of the sealing body, and a source lead and a gate lead which project in parallel from one side surface of the sealing body, and wires which are positioned in the inside of the sealing body and connect electrodes on an upper surface of the semiconductor chip and the source lead and the gate lead, with a gate electrode pad arranged at a position from the gate lead and the source lead farther than a source electrode pad.

A semiconductor device includes: a semiconductor chip; and an Ag fired cap formed so as to cover a source pad electrode formed on the semiconductor chip. The semiconductor chip is disposed on a first substrate electrode, and one end of a Cu wire is bonded onto the Ag fired cap by means of an ultrasonic wave. There is provided a semiconductor device capable of improving a power cycle capability, and a fabrication method of such a semiconductor device.

A power module (PM) includes: an insulating substrate; a semiconductor device disposed on the insulating substrate, the semiconductor device including electrodes on a front surface side and a back surface side thereof; and a graphite plate having an anisotropic thermal conductivity, the graphite plate of which one end is connected to the front surface side of the semiconductor device and the other end is connected to the insulating substrate, wherein heat of the front surface side of the semiconductor device is transferred to the insulating substrate through the graphite plate. There is provide an inexpensive power module capable of reducing a stress and capable of exhibiting cooling performance not inferior to that of the double-sided cooling structures.

A method of manufacturing a semiconductor device includes forming an interlayer insulating film over a main surface of a semiconductor substrate, forming a first conductive film pattern for a first pad and a second conductive film pattern for a second pad over the interlayer insulating film, forming an insulating film over the interlayer insulating film such that the insulating film covers the first and the second conductive film patterns, forming a first opening portion for the first pad, the first opening portion exposing a portion of the first conductive film pattern, and a second opening portion for the second pad, the second opening portion exposing a portion of the second conductive film pattern, in the insulating film, and forming a first plated layer by plating over the portion of the first conductive film pattern exposed in the first opening portion, and a second plated layer.

An electrode terminal includes a body and a first bonding part. The body includes a first metal material. Then, the first bonding part is bonded to one end of the body, and includes a second metal material which is a clad material other than the first metal material. The first bonding part is ultrasonically bondable to a first bonded member. An elastic part which is elastically deformable is provided between the one end of the body and the other end of the body.

In a power semiconductor module, the 0.2% yield strength of solder under a lead terminal that bonds the lead terminal and a semiconductor element is set to be lower than the 0.2% yield strength of solder under the semiconductor element that bonds the semiconductor element and an insulating substrate. As a result, the lead terminal is expanded with self-heating by energization of the semiconductor element, and stress is applied to the semiconductor element via the solder under the lead terminal. However, the solder under the lead terminal with low 0.2% yield strength reduces the stress that is applied to the semiconductor element. Thus, the reliability of a surface electrode of the semiconductor element that is bonded to the solder under the lead terminal is improved.

A semiconductor device includes a semiconductor die attached to a substrate and a metal clip attached to a side of the semiconductor die facing away from the substrate by a soldered joint. The metal clip has a plurality of slots dimensioned so as to take up at least 10% of a solder paste reflowed to form the soldered joint. Corresponding methods of production are also described.

Semiconductor device A1 of the present disclosure includes: semiconductor element 10 (semiconductor elements 10A and 10B) having element obverse face and element reverse face facing toward opposite sides in z direction; support substrate 20 supporting semiconductor element 10; conductive block 60 (first block 61 and second block 62) bonded to element obverse face via first conductive bonding material (block bonding materials 610 and 620); and metal member (lead member 40 and input terminal 32) electrically connected to semiconductor element 10 via conductive block 60. Conductive block 60 has a thermal expansion coefficient smaller than that of metal member. Conductive block 60 and metal member are bonded to each other by a weld portion (weld portions M4 and M2) at which a portion of conductive block 60 and a portion of metal member are welded to each other. Thus, the thermal cycle resistance can be improved.

A semiconductor package fabrication method comprises the steps of providing a wafer, applying a seed layer, forming a photo resist layer, plating a copper layer, removing the photo resist layer, removing the seed layer, applying a grinding process, forming metallization, and applying a singulation process. A semiconductor package comprises a silicon layer, an aluminum layer, a passivation layer, a polyimide layer, a copper layer, and metallization. In one example, an area of a contact area of a gate clip is smaller than an area of a gate copper surface. The area of the contact area of the gate clip is larger than a gate aluminum surface. In another example, an area of a contact area of a gate pin is larger than an area of a gate copper surface. The area of the contact area of the gate pin is larger than a gate aluminum surface.

The semiconductor device includes a supporting member, a conductive member, and a semiconductor element. The supporting member has a supporting surface facing in a thickness direction. The conductive member has an obverse surface facing the same side as the supporting surface faces in the thickness direction, and a reverse surface opposite to the obverse surface. The conductive member is bonded to the supporting member such that the reverse surface faces the supporting surface. The semiconductor element is bonded to the obverse surface. The semiconductor device further includes a first metal layer and a second metal layer. The first metal layer covers at least a part of the supporting surface. The second metal layer covers the reverse surface. The first metal layer and the second layer are bonded to each other by solid phase diffusion.