An object of the present invention is to provide a power module that secures a heat dissipation route and has increased reliability. A power module of the present invention includes a first circuit body having a first semiconductor element and a first conductor portion, a second circuit body having a second semiconductor element and a second conductor portion, a resin sealing material for sealing the first circuit body and the second circuit body, and a warpage suppression portion that is formed along an array direction of the first circuit body and the second circuit body and is formed to have greater rigidity than a sealing portion of the resin sealing material, wherein the warpage suppression portion is formed of the same material as a resin member of the resin sealing material and is formed to be thicker than the sealing portion of the resin sealing material.

An object of the present invention is to provide a power module that secures a heat dissipation route and has increased reliability. A power module of the present invention includes a first circuit body having a first semiconductor element and a first conductor portion, a second circuit body having a second semiconductor element and a second conductor portion, a resin sealing material for sealing the first circuit body and the second circuit body, and a warpage suppression portion that is formed along an array direction of the first circuit body and the second circuit body and is formed to have greater rigidity than a sealing portion of the resin sealing material, wherein the warpage suppression portion is formed of the same material as a resin member of the resin sealing material and is formed to be thicker than the sealing portion of the resin sealing material.

An apparatus includes a wafer portion and a plurality of die fabricated in the wafer portion in a defined pattern such that the die are separated from each other by a dicing area or a street. The apparatus includes a conductive connection between given adjacent die. The conductive connection is electrically coupled to circuitry disposed on the given adjacent die.

An apparatus includes a wafer portion and a plurality of die fabricated in the wafer portion in a defined pattern such that the die are separated from each other by a dicing area or a street. The apparatus includes a conductive connection between given adjacent die. The conductive connection is electrically coupled to circuitry disposed on the given adjacent die.

A power semiconductor package is disclosed. The power semiconductor package includes a leadframe having partially etched segments and at least one non-etched segment, a first semiconductor die having a first power transistor and a driver integrated circuit (IC) monolithically formed thereon, a second semiconductor die having a second power transistor, wherein the first semiconductor die and the second semiconductor die are configured for attachment to the partially etched segments, and wherein the partially etched segments and the at least one non-etched segment enable the first semiconductor die to be coupled to the second semiconductor die by a legless conductive clip.

A power semiconductor package is disclosed. The power semiconductor package includes a leadframe having partially etched segments and at least one non-etched segment, a first semiconductor die having a first power transistor and a driver integrated circuit (IC) monolithically formed thereon, a second semiconductor die having a second power transistor, wherein the first semiconductor die and the second semiconductor die are configured for attachment to the partially etched segments, and wherein the partially etched segments and the at least one non-etched segment enable the first semiconductor die to be coupled to the second semiconductor die by a legless conductive clip.

Provided are: a sintering binder including nanoparticles, a method for producing the sintering binder, and a method for bonding using the sintering binder. The sintering binder mainly includes cuprous oxide nanoparticles, combines particle stability with bondability, and less undergoes ion migration. A composite particle including metallic copper with the remainder being cuprous oxide and inevitable impurities is used for bonding typically of metals. The composite particle structurally includes metallic copper dispersed inside the particle and has an average particle size of 1000 nm or less.

Provided are: a sintering binder including nanoparticles, a method for producing the sintering binder, and a method for bonding using the sintering binder. The sintering binder mainly includes cuprous oxide nanoparticles, combines particle stability with bondability, and less undergoes ion migration. A composite particle including metallic copper with the remainder being cuprous oxide and inevitable impurities is used for bonding typically of metals. The composite particle structurally includes metallic copper dispersed inside the particle and has an average particle size of 1000 nm or less.

An object of the present invention is to provide a semiconductor module with high heat dissipation at a low cost. A semiconductor module according to the present invention includes: a case having a hollow portion; a base board made of an aluminum alloy having a first portion corresponding to the hollow portion of the case, and a second portion corresponding to a main body portion of the case, the base board being attached to a bottom face of the case via the second portion; a ceramic insulating substrate disposed on the first portion of the base board; a wiring pattern disposed on the ceramic insulating substrate; semiconductor elements disposed on the wiring pattern; metal wiring boards connected to the semiconductor elements; and a sealing resin that seals the hollow portion of the case.

An object of the present invention is to provide a semiconductor module with high heat dissipation at a low cost. A semiconductor module according to the present invention includes: a case having a hollow portion; a base board made of an aluminum alloy having a first portion corresponding to the hollow portion of the case, and a second portion corresponding to a main body portion of the case, the base board being attached to a bottom face of the case via the second portion; a ceramic insulating substrate disposed on the first portion of the base board; a wiring pattern disposed on the ceramic insulating substrate; semiconductor elements disposed on the wiring pattern; metal wiring boards connected to the semiconductor elements; and a sealing resin that seals the hollow portion of the case.