In a method for producing an electronic part mounting substrate wherein an electronic part 14 is mounted on one major surface (a surface to which the electronic part 14 is to be bonded) of the metal plate 10 of copper, or aluminum or the aluminum alloy (when a plating film 20 of copper is formed on the surface), the one major surface of the metal plate 10 (or the surface of the plating film 20 of copper) is surface-machined to be coarsened so as to have a surface roughness of not less than 0.4 μm, and then, a silver paste is applied on the surface-machined major surface (or the surface-machined surface of the plating film 20 of copper) to arrange the electronic part 14 thereon to sinter silver in the silver paste to form a silver bonding layer 12 to bond the electronic part 14 to the one major surface of the metal plate 10 (or the surface of the plating film 20 of copper) with the silver bonding layer 12.

A bonding structure production method for producing a bonding structure (100) includes at least bonding a semiconductor element (30) and a substrate (10) using a silver paste. The substrate (10) includes a die attachment portion (12) to which the semiconductor element (30) is to be bonded. The die attachment portion (12) includes an alumina layer (16) serving as a surface layer on a bonding side of the die attachment portion (12) to which the semiconductor element (30) is to be bonded. The silver paste contains a solvent and silver particles with a residual strain measured by X-ray diffractometry of at least 5.0%. Preferably, the silver particles have a volume-based 50% cumulative diameter of at least 100 nm and no greater than 50 μm.

Devices and methods disclosed herein can include a conductive foam having pores disposed within the conductive foam. The conductive foam can be compressible between an uncompressed thickness and a compressed thickness. The compressed thickness can be ninety-five percent or less of the uncompressed thickness. In one example, a filler can be disposed in the pores of the conductive foam. The filler can include a first thermal conductivity. The first thermal conductivity can be greater than a thermal conductivity of air.

Devices and methods disclosed herein can include a conductive foam having pores disposed within the conductive foam. The conductive foam can be compressible between an uncompressed thickness and a compressed thickness. The compressed thickness can be ninety-five percent or less of the uncompressed thickness. In one example, a filler can be disposed in the pores of the conductive foam. The filler can include a first thermal conductivity. The first thermal conductivity can be greater than a thermal conductivity of air.

To reduce substrate warp occurring after connection an anisotropic conductive film is used. An anisotropic conductive film has: a first insulating adhesive layer; a second insulating adhesive layer; and a conductive particle-containing layer sandwiched by the first insulating adhesive layer and the second insulating adhesive layer and having conductive particles contained in an insulating adhesive, wherein air bubbles are contained between the conductive particle-containing layer and the first insulating adhesive layer, and, the conductive particle-containing layer, a portion thereof below the conductive particles and in contact with the second insulating adhesive layer has a lower degree of cure than other portions thereof.

To reduce substrate warp occurring after connection an anisotropic conductive film is used. An anisotropic conductive film has: a first insulating adhesive layer; a second insulating adhesive layer; and a conductive particle-containing layer sandwiched by the first insulating adhesive layer and the second insulating adhesive layer and having conductive particles contained in an insulating adhesive, wherein air bubbles are contained between the conductive particle-containing layer and the first insulating adhesive layer, and, the conductive particle-containing layer, a portion thereof below the conductive particles and in contact with the second insulating adhesive layer has a lower degree of cure than other portions thereof.

A bonding structure production method for producing a bonding structure (100) includes at least bonding a semiconductor element (30) and a substrate (10) using a silver paste. The substrate (10) includes a die attachment portion (12) to which the semiconductor element (30) is to be bonded. The die attachment portion (12) includes an alumina layer (16) serving as a surface layer on a bonding side of the die attachment portion (12) to which the semiconductor element (30) is to be bonded. The silver paste contains a solvent and silver particles with a residual strain measured by X-ray diffractometry of at least 5.0%. Preferably, the silver particles have a volume-based 50% cumulative diameter of at least 100 nm and no greater than 50 ?m.

To reduce substrate warp occurring after connection an anisotropic conductive film is used. An anisotropic conductive film has: a first insulating adhesive layer; a second insulating adhesive layer; and a conductive particle-containing layer sandwiched by the first insulating adhesive layer and the second insulating adhesive layer and having conductive particles contained in an insulating adhesive, wherein air bubbles are contained between the conductive particle-containing layer and the first insulating adhesive layer, and, the conductive particle-containing layer, a portion thereof below the conductive particles and in contact with the second insulating adhesive layer has a lower degree of cure than other portions thereof.

To reduce substrate warp occurring after connection an anisotropic conductive film is used. An anisotropic conductive film has: a first insulating adhesive layer; a second insulating adhesive layer; and a conductive particle-containing layer sandwiched by the first insulating adhesive layer and the second insulating adhesive layer and having conductive particles contained in an insulating adhesive, wherein air bubbles are contained between the conductive particle-containing layer and the first insulating adhesive layer, and, the conductive particle-containing layer, a portion thereof below the conductive particles and in contact with the second insulating adhesive layer has a lower degree of cure than other portions thereof.

To reduce substrate warp occurring after connection an anisotropic conductive film is used. An anisotropic conductive film has: a first insulating adhesive layer; a second insulating adhesive layer; and a conductive particle-containing layer sandwiched by the first insulating adhesive layer and the second insulating adhesive layer and having conductive particles contained in an insulating adhesive, wherein air bubbles are contained between the conductive particle-containing layer and the first insulating adhesive layer, and, the conductive particle-containing layer, a portion thereof below the conductive particles and in contact with the second insulating adhesive layer has a lower degree of cure than other portions thereof.