A semiconductor device includes a conductive member having an obverse face, a semiconductor element mounted on the obverse face, and a conductive bonding material disposed between the conductive member and the semiconductor element, to conductively bond the conductive member and the semiconductor element together. The conductive bonding material includes a metal base layer, a first bonding layer, and a second bonding layer. The first bonding layer is disposed between the metal base layer and the semiconductor element, and bonded to the semiconductor element by metal solid-phase diffusion. The second bonding layer is disposed between the metal base layer and the conductive member, and bonded to the conductive member by metal solid-phase diffusion.

A process for the production of a permanent, electrically conductive connection between a first metal surface of a first substrate and a second metal surface of a second substrate, wherein a permanent, electrically conductive connection is produced, at least primarily, by substitution diffusion between metal ions and/or metal atoms of the two metal surfaces.

A process for the production of a permanent, electrically conductive connection between a first metal surface of a first substrate and a second metal surface of a second substrate, wherein a permanent, electrically conductive connection is produced, at least primarily, by substitution diffusion between metal ions and/or metal atoms of the two metal surfaces.

A semiconductor device structure and method of manufacturing a semiconductor device is provided. The method includes providing a first semiconductor substrate having a first major surface and an opposing second major surface, the first major surface having a first metal layer formed thereon; providing a second semiconductor substrate having a first major surface and an opposing second major surface, with the second semiconductor substrate including a plurality of active device regions formed therein and a second metal layer formed on the first major surface connecting each of the plurality of active device regions; bonding the first metal layer of the first semiconductor substrate to the second metal layer of the second semiconductor substrate; and forming device contacts on the second major surface of the second semiconductor substrate for electrical connection to each of the plurality of active device regions.

A semiconductor device includes a first circuit, a second circuit, a wiring member, and a bonding material. The wiring member is connected to one of the first circuit and the second circuit. The bonding material is connected to the other of the first circuit and the second circuit. The wiring member includes a first end, a second end, and a top. The first end and the second end are connected to one of the first circuit and the second circuit. The top is located between the first end and the second end. The top is connected to the other of the first circuit and the second circuit with the bonding material in between.

A semiconductor device includes a first circuit, a second circuit, a wiring member, and a bonding material. The wiring member is connected to one of the first circuit and the second circuit. The bonding material is connected to the other of the first circuit and the second circuit. The wiring member includes a first end, a second end, and a top. The first end and the second end are connected to one of the first circuit and the second circuit. The top is located between the first end and the second end. The top is connected to the other of the first circuit and the second circuit with the bonding material in between.

A power module according implementations of the present disclosure includes a bonding layer for bonding two adjacent members. The bonding layer is formed by melting, applying, and solidifying a bonding material that has excellent thermal conductivity and electrical conductivity. The melted bonding material includes a plurality of anti-tilting members. The two members bonded during the process of solidifying the melted bonding material are supported by the plurality of anti-tilting members. This may allow tilting caused during the formation of the bonding layer to be suppressed.

A power module according implementations of the present disclosure includes a bonding layer for bonding two adjacent members. The bonding layer is formed by melting, applying, and solidifying a bonding material that has excellent thermal conductivity and electrical conductivity. The melted bonding material includes a plurality of anti-tilting members. The two members bonded during the process of solidifying the melted bonding material are supported by the plurality of anti-tilting members. This may allow tilting caused during the formation of the bonding layer to be suppressed.

A semiconductor module includes: a conductive substrate having an obverse surface and a reverse surface spaced apart in a thickness direction; a semiconductor element electrically bonded to the obverse surface and having a switching function; and a conducting member that forms a path of a main circuit current switched by the semiconductor element. The semiconductor element has a rectangular shape with four corners as viewed in the thickness direction. The conducting member includes a portion overlapping with the semiconductor element as viewed in the thickness direction. The conducting member do not overlap with at least three of the four corners of the semiconductor element.

A semiconductor module includes a conductive substrate, a plurality of first semiconductor elements, and a plurality of second semiconductor elements. The conductive substrate includes a first conductive portion to which the plurality of first semiconductor elements are electrically bonded, and a second conductive portion to which the plurality of second semiconductor elements are electrically bonded. The semiconductor module further includes a first input terminal, a second input terminal, and a third input terminal that are provided near the first conductive portion. The second input terminal and the third input terminal are spaced apart from each other with the first input terminal therebetween. The first input terminal is electrically connected to the first conductive portion. A polarity of the first input terminal is set to be opposite to a polarity of each of the second input terminal and the third input terminal.