In a method of manufacturing a power module unit, cooling fins are positioned in recesses of a frame, in particular a metal frame. A first metallic material is applied to the cooling fins and the frame by a thermal spraying process, causing the applied first metallic material to produce a material bond between the cooling fins and the frame.

An electronic device includes a semiconductor substrate and a heat sink arranged on a surface of the semiconductor substrate. The heat sink includes a plurality of metal filaments that each includes a first end joined to the surface, a second end, and a body over the surface such that the body is surrounded by a coolant medium to dissipate heat. The heat sink is not part of an electrical network.

A signal-heat separated TMV packaging structure includes an insulating dielectric material, an inner signal line layer arranged in the insulating dielectric material, an outer signal line layer, a heat dissipation metal face and a chip. A first side of the insulating dielectric material is provided with an isolating layer. The outer signal line layer is arranged on a surface of a second side of the insulating dielectric material and is connected with the inner signal line layer through a TMV structure. The heat dissipation metal face is arranged on a surface of the first side of the insulating dielectric material, and is separated from the inner signal line layer. The chip is embedded in the insulating dielectric material, with an active face in electrically-conductive connection with the inner signal line layer and a passive face in heat transfer connection with the heat dissipation metal face.

A manufacturing method of an electronic-component-mounted module includes a step of forming a laminate of: a ceramic substrate board, a circuit layer made of aluminum or aluminum alloy on the ceramic substrate board, a first silver paste layer between the circuit layer and one surface of an electronic component, the electronic component, a lead frame made of copper or copper alloy, and a second silver paste layer between the other surface of the electronic component and the lead frame; and a step of batch-bonding bonding the circuit layer, the electronic component, and the lead frame at one time by heating the laminate to a heating temperature of not less than 180° C. to 350° C. inclusive with adding a pressure of 1 MPa to 20 MPa inclusive in a laminating direction on the laminate, to sinter the first and second silver paste layers and form first and second silver-sintered bonding layers.

A power semiconductor apparatus includes a mold portion, a panel that is conductive and in a flat plate shape, and a plurality of fins. The mold portion includes a power semiconductor element and a base plate that are molded. An opening is formed in the panel into which the base plate is inserted. The plurality of fins is fixed in grooves of the base plate. The panel has a plurality of protrusions on side surfaces forming the opening. Each protrusion has a fifth surface a cross section of which has a shape that tapers down toward an end of the protrusion, the cross section being parallel to a plane extending in the Z direction and a direction in which the protrusion protrudes. The base plate has cover portions covering the fifth surfaces, and is plastically deformed to allow the panel to be fitted in the base plate to fill gaps.

A semiconductor device, including a metal base plate having a front surface on which a disposition area is set apart from a central portion of the metal base plate, and a board placed over the disposition area with a solder therebetween. The solder has two edge portions of which one is closer than the other to the central portion of the metal base plate, said one being thicker than said the other.

A system includes at least one component configured to generate thermal energy, a heat spreader configured to remove thermal energy from the at least one component, and at least one substrate configured to remove thermal energy from the heat spreader. The heat spreader includes a first portion and a second portion. The first portion of the heat spreader is coupled to the substrate, and the second portion of the heat spreader is coupled to the at least one component. The first portion of the heat spreader includes high aspect-ratio structures that are separated from one another. The high aspect-ratio structures cause the first portion of the heat spreader to be pliable and able to accommodate a mismatch in coefficients of thermal expansion between a material in the heat spreader and a material in the substrate.

A method includes providing a first metal sheet and a second metal sheet, printing a plurality of channels on the first metal sheet, bonding the first metal sheet and the second metal sheet to each other to obtain a fin body, bending a first portion of the fin body to be transverse to a second portion of the fin body, separating the first metal sheet and the second metal sheet from each other to form the plurality of channels, introducing working fluid in the plurality of channels, and sealing the first metal sheet and the second metal sheet.

A semiconductor package includes; a package substrate, an interposer disposed on the package substrate, semiconductor chips mounted on the interposer, a molding member on the interposer and surrounding the semiconductor chips, a first sealing member on the molding member, and a heat dissipation member on the package substrate and covering the interposer, the semiconductor chips, and the first sealing member, wherein the heat dissipation member includes a lower structure contacting an upper surface of the package substrate, and an upper structure on the lower structure, extending over the first sealing member, and including a microchannel and a micropillar on the microchannel.

An IC die includes a temperature control element suitable for three-dimensional IC package with enhanced thermal control and management. The temperature control element may be formed as an integral part of an IC die that may assist temperature control of the IC die when in operation. The temperature control element may include a heat dissipation material disposed therein to assist dissipating thermal energy generated by the plurality of devices in the IC die during operation.