A power semiconductor device includes a substrate and a semiconductor element bonded onto a first surface of the substrate through use of a sintered metal bonding material. The substrate has a plurality of dimples formed in the first surface and located outside a location immediately below a heat generation unit of the semiconductor element. The sintered metal bonding material is supplied onto the substrate after the formation of the dimples, and the semiconductor element is bonded to the substrate through application of heat and a pressure thereto.

A power semiconductor device includes a substrate and a semiconductor element bonded onto a first surface of the substrate through use of a sintered metal bonding material. The substrate has a plurality of dimples formed in the first surface and located outside a location immediately below a heat generation unit of the semiconductor element. The sintered metal bonding material is supplied onto the substrate after the formation of the dimples, and the semiconductor element is bonded to the substrate through application of heat and a pressure thereto.

This member connection method includes: a cutting step of forming cutting lines C in an adhesive layer at predetermined intervals at least in a width direction of an adhesive tape and making segments of the adhesive layer divided by the cutting lines C continuous at least in a lengthwise direction of the adhesive tape; a transfer step of disposing the segments to face a connection surface of one member to be connected, pressing a heating and pressing tool having an arbitrary pattern shape against the adhesive tape from a separator side and selectively transferring the segments to the one member to be connected; and a connection step for connecting another member to be connected to the one member to be connected via the segments transferred to the one member to be connected.

This member connection method includes: a cutting step of forming cutting lines C in an adhesive layer at predetermined intervals at least in a width direction of an adhesive tape and making segments of the adhesive layer divided by the cutting lines C continuous at least in a lengthwise direction of the adhesive tape; a transfer step of disposing the segments to face a connection surface of one member to be connected, pressing a heating and pressing tool having an arbitrary pattern shape against the adhesive tape from a separator side and selectively transferring the segments to the one member to be connected; and a connection step for connecting another member to be connected to the one member to be connected via the segments transferred to the one member to be connected.

A bonding film for bonding a semiconductor element and a substrate. The bonding film has an electroconductive bonding layer formed by molding an electroconductive paste including metal fine particles (P) into a film form, and a tack layer having tackiness and laminated on the electroconductive bonding layer. The tack layer includes 0.1% to 1.0% by mass of metal fine particles (M) with respect to the metal fine particles (P) in the electroconductive bonding layer, and the metal fine particles (M) have a melting point of 250° C. or lower.

A bonding film for bonding a semiconductor element and a substrate. The bonding film has an electroconductive bonding layer formed by molding an electroconductive paste including metal fine particles (P) into a film form, and a tack layer having tackiness and laminated on the electroconductive bonding layer. The tack layer includes 0.1% to 1.0% by mass of metal fine particles (M) with respect to the metal fine particles (P) in the electroconductive bonding layer, and the metal fine particles (M) have a melting point of 250° C. or lower.

A platform for hermetic heterogeneous integration of passive and active electronic components is provided herein. The platform can include a substrate that provides a hermetic electrical interconnection between integrated circuits and passive devices, such as resistors, capacitors, and inductors. Such substrates can be formed of a dielectric, such as a ceramic, and include electrical interconnects and can further include one or more passive devices. The substrate can include one or more cavities, at least a primary cavity dimensioned to receive an active device and one or more secondary cavities can be included for secondary connector pads for interfacing with the active and passive devices and which can be separately hermetically sealed. The substrate can include a multi-coil inductor defined within alternating layers of the substrate within sidewalls that surround the primary cavity to minimize size of the device package while optimizing the size of the coil.

A platform for hermetic heterogeneous integration of passive and active electronic components is provided herein. The platform can include a substrate that provides a hermetic electrical interconnection between integrated circuits and passive devices, such as resistors, capacitors, and inductors. Such substrates can be formed of a dielectric, such as a ceramic, and include electrical interconnects and can further include one or more passive devices. The substrate can include one or more cavities, at least a primary cavity dimensioned to receive an active device and one or more secondary cavities can be included for secondary connector pads for interfacing with the active and passive devices and which can be separately hermetically sealed. The substrate can include a multi-coil inductor defined within alternating layers of the substrate within sidewalls that surround the primary cavity to minimize size of the device package while optimizing the size of the coil.

Provided is a semiconductor device including: a bed having a bed surface; a semiconductor chip having a bottom surface larger than the bed surface, the semiconductor chip being provided such that a center of the bottom surface is disposed above the bed surface and the bottom surface having a first end and a second end; a joint material provided between the bed surface and the bottom surface; a plate-like first wire having a first surface and provided such that the first surface faces the first end; a plate-like second wire having a second surface and provided such that the second surface faces the second end; a first insulating film having a third surface and a fourth surface provided on an opposite side of the third surface, the third surface being in contact with the first end, the fourth surface being in contact with the first surface; and a second insulating film having a fifth surface and a sixth surface provided on an opposite side of the fifth surface, the fifth surface being in contact with the second end, the sixth surface being in contact with the first surface.

Provided is a semiconductor device including: a bed having a bed surface; a semiconductor chip having a bottom surface larger than the bed surface, the semiconductor chip being provided such that a center of the bottom surface is disposed above the bed surface and the bottom surface having a first end and a second end; a joint material provided between the bed surface and the bottom surface; a plate-like first wire having a first surface and provided such that the first surface faces the first end; a plate-like second wire having a second surface and provided such that the second surface faces the second end; a first insulating film having a third surface and a fourth surface provided on an opposite side of the third surface, the third surface being in contact with the first end, the fourth surface being in contact with the first surface; and a second insulating film having a fifth surface and a sixth surface provided on an opposite side of the fifth surface, the fifth surface being in contact with the second end, the sixth surface being in contact with the first surface.