A semiconductor device includes: a substrate; a semiconductor element arranged on the substrate; a plate-like member electrically connected to the semiconductor element; a first electrode formed on the semiconductor element and joined to the plate-like member with solder; a second electrode formed on the semiconductor element and spaced from the first electrode, and including a metal capable of forming an alloy with the solder; and a metal film formed on the semiconductor element and spaced from the second electrode in a region on the first electrode side as seen from the second electrode, in a two-dimensional view of the semiconductor element as seen from the plate-like member, and including a metal capable of forming an alloy with the solder.

A method of manufacturing a semiconductor device includes providing, in a housing, an insulating substrate having a metal pattern, a semiconductor chip, a sinter material applied on the semiconductor chip, and a terminal, providing multiple granular sealing resins supported by a grid provided in the housing, heating an inside of the housing until a temperature thereof reaches a first temperature higher than a room temperature and thereby discharging a vaporized solvent of the sinter material out of the housing via a gap of the grid and a gap of the sealing resins, and heating the inside of the housing until the temperature thereof reaches a second temperature higher than the first temperature and thereby causing the melted sealing resins to pass the gap of the grid and form a resin layer covering the semiconductor chip.

A semiconductor device, including a capacitor, a semiconductor module having a first power terminal formed on a front surface of a first insulating member, and a connecting member electrically connecting and mechanically coupling the semiconductor module and the capacitor to each other, the connecting member having a front surface and a rear surface opposite to each other, the rear surface being on a front surface of the first power terminal. The connecting member is bonded to the semiconductor module via a first welded portion, which penetrates the front and rear surfaces of the connecting member, and penetrates the front surface of the first power terminal, in a thickness direction of the semiconductor device, a distance in the thickness direction between a bottommost portion of first welded portion and the front surface of the first insulating member being 0.3 mm or more.

A power module includes a power semiconductor element, an interconnection material, a circuit board, an external terminal, a joining material, and a sealing resin. A clearance portion is continuously formed between the sealing resin and each of an end surface of the joining material and a surface of the interconnection material so as to extend from the end surface of the joining material to the surface of the interconnection material, the end surface of the joining material being located between the power semiconductor element and the interconnection material, the surface of the interconnection material being located between the end surface and a predetermined position of the interconnection material separated by a distance from the end surface.

Semiconductor device A1 of the present disclosure includes: semiconductor element 10 (semiconductor elements 10A and 10B) having element obverse face and element reverse face facing toward opposite sides in z direction; support substrate 20 supporting semiconductor element 10; conductive block 60 (first block 61 and second block 62) bonded to element obverse face via first conductive bonding material (block bonding materials 610 and 620); and metal member (lead member 40 and input terminal 32) electrically connected to semiconductor element 10 via conductive block 60. Conductive block 60 has a thermal expansion coefficient smaller than that of metal member. Conductive block 60 and metal member are bonded to each other by a weld portion (weld portions M4 and M2) at which a portion of conductive block 60 and a portion of metal member are welded to each other. Thus, the thermal cycle resistance can be improved.

A semiconductor device, including a capacitor, a semiconductor module having a first power terminal formed on a front surface of a first insulating member, and a connecting member electrically connecting and mechanically coupling the semiconductor module and the capacitor to each other, the connecting member having a front surface and a rear surface opposite to each other, the rear surface being on a front surface of the first power terminal. The connecting member is bonded to the semiconductor module via a first welded portion, which penetrates the front and rear surfaces of the connecting member, and penetrates the front surface of the first power terminal, in a thickness direction of the semiconductor device, a distance in the thickness direction between a bottommost portion of first welded portion and the front surface of the first insulating member being 0.3 mm or more.

A method of manufacturing a semiconductor device includes providing, in a housing, an insulating substrate having a metal pattern, a semiconductor chip, a sinter material applied on the semiconductor chip, and a terminal, providing multiple granular sealing resins supported by a grid provided in the housing, heating an inside of the housing until a temperature thereof reaches a first temperature higher than a room temperature and thereby discharging a vaporized solvent of the sinter material out of the housing via a gap of the grid and a gap of the sealing resins, and heating the inside of the housing until the temperature thereof reaches a second temperature higher than the first temperature and thereby causing the melted sealing resins to pass the gap of the grid and form a resin layer covering the semiconductor chip.

Provided is a semiconductor package including a heat radiation structure, a cooling system applying the semiconductor package, a substrate including a heat radiation structure, and a method of manufacturing the substrate, and more particularly, a semiconductor package including a heat radiation structure, a cooling system applying the semiconductor package, a substrate including a heat radiation structure, and a method of manufacturing the substrate, in which an area contacting a coolant enlarges through heat radiating posts having various forms and structures and a coolant flow path is formed by post holes so that heat generated from semiconductor chips may be efficiently cooled.

Disclosed are a power module and a method for manufacturing the same. A power module according to an embodiment of the present disclosure includes: a first substrate; a second substrate disposed spaced apart from the first substrate and including at least one metal layer; at least one chip disposed between the first substrate and the second substrate and in electrical contact with the metal layer; and a third substrate configured to be disposed spaced apart from the first substrate and the second substrate, electrically connect the chip and at least one external input terminal, include one or more conductive patterns each of which is connected to one of the at least one lead frame, and be formed in a multi-layer structure such that the one or more conductive patterns are not short-circuited to each other.

A semiconductor device includes: a substrate; a semiconductor element arranged on the substrate; a plate-like member electrically connected to the semiconductor element; a first electrode formed on the semiconductor element and joined to the plate-like member with solder; a second electrode formed on the semiconductor element and spaced from the first electrode, and including a metal capable of forming an alloy with the solder; and a metal film formed on the semiconductor element and spaced from the second electrode in a region on the first electrode side as seen from the second electrode, in a two-dimensional view of the semiconductor element as seen from the plate-like member, and including a metal capable of forming an alloy with the solder.