There is provided a bonding material which forms a bonding portion between two objects, which material contains (1) first metal particles comprising a first metal and having a median particle diameter in the range of 20 nm to 1 μm, and (2) second metal particles comprising, as a second metal, at least one alloy of Sn and at least one selected from Bi, In and Zn and having a melting point of not higher than 200° C.

A semiconductor device 10 includes a pair of electrodes 16 and a conductive connection member 21 electrically bonded to the pair of electrodes 16. At least a portion of a perimeter of a bonding surface 24 of at least one of the pair of electrodes 16 and the conductive connection member 21 includes an electromigration reducing area 22.

The object of the technique disclosed in the specification is to provide a technique in which the production cost is reduced without impairing the mechanical strength of the resin, and the heat radiation is improved. The semiconductor device relates to the technique disclosed in the specification includes an insulating substrate, a semiconductor element disposed on an upper surface of the insulating substrate, a case connected to the insulating substrate, such that the semiconductor element is accommodated inside thereof, and resin filled inside of the case, such that the semiconductor element is embedded, on the upper surface of the resin in the inside of the case, a first concave part is formed, the first concave part is formed at a position covering an entire of the semiconductor element in plan view.

There is provided a bonding material which forms a bonding portion between two objects, which material contains (1) first metal particles comprising a first metal and having a median particle diameter in the range of 20 nm to 1 m, and (2) second metal particles comprising, as a second metal, at least one alloy of Sn and at least one selected from Bi, In and Zn and having a melting point of not higher than 200 C.

A method for applying a bonding layer that is comprised of a basic layer and a protective layer on a substrate with the following method steps: application of an oxidizable basic material as a basic layer on a bonding side of the substrate, at least partial covering of the basic layer with a protective material that is at least partially dissolvable in the basic material as a protective layer. In addition, the invention relates to a corresponding substrate.

The object of the technique disclosed in the specification is to provide a technique in which the production cost is reduced without impairing the mechanical strength of the resin, and the heat radiation is improved. The semiconductor device relates to the technique disclosed in the specification includes an insulating substrate, a semiconductor element disposed on an upper surface of the insulating substrate, a case connected to the insulating substrate, such that the semiconductor element is accommodated inside thereof, and resin filled inside of the case, such that the semiconductor element is embedded, on the upper surface of the resin in the inside of the case, a first concave part is formed, the first concave part is formed at a position covering an entire of the semiconductor element in plan view.

A semiconductor device 10 includes a pair of electrodes 16 and a conductive connection member 21 electrically bonded to the pair of electrodes 16. At least a portion of a perimeter of a bonding surface 24 of at least one of the pair of electrodes 16 and the conductive connection member 21 includes an electromigration reducing area 22.

An improved structure for reducing compound semiconductor wafer distortion comprises a contact metal layer formed on a bottom surface of a compound semiconductor wafer, at least one stress balance layer formed on a bottom surface of the contact metal layer and made of nonconductive material, stress balance layer via holes and a die attachment layer. Each stress balance layer via hole penetrates the stress balance layer. The die attachment layer is made of conductive material, formed on a bottom surface of the stress balance layer and an inner surface of each stress balance layer via hole, and electrically connected with the contact metal layer through the stress balance layer via holes. By locating the stress balance layer between the contact metal layer and the die attachment layer, the stress suffered by the compound semiconductor wafer is balanced so that the distortion of the compound semiconductor wafer is reduced.

A method for applying a bonding layer that is comprised of a basic layer and a protective layer on a substrate with the following method steps: application of an oxidizable basic material as a basic layer on a bonding side of the substrate, at least partial covering of the basic layer with a protective material that is at least partially dissolvable in the basic material as a protective layer. In addition, the invention relates to a corresponding substrate.

A method for applying a bonding layer that is comprised of a basic layer and a protective layer on a substrate with the following method steps: application of an oxidizable basic material as a basic layer on a bonding side of the substrate, at least partial covering of the basic layer with a protective material that is at least partially dissolvable in the basic material as a protective layer. In addition, the invention relates to a corresponding substrate.