An electronic module has a first substrate 11, a first electronic element 13, a second electronic element 23, a second substrate 21, a first terminal part 110 provided on a side of the first substrate 11 and a second terminal part 120 provided on a side of the second substrate 21. The first terminal part 110 has a first surface direction extending part 114 and a first normal direction extending part 113 extending toward one side or the other side. The second terminal part 120 has a second surface direction extending part 124 and a second normal direction extending part 123 extending toward one side or the other side. The second surface direction extending part 124 is provided on one side of the first surface direction extending part 114, and the first surface direction extending part 114 and the second surface direction extending part 124 overlap one another in a surface direction.

Embodiments may relate to a microelectronic package that includes a die coupled with a package substrate. A solder thermal interface material (STIM) may be coupled with the die such that the die is between the STIM and the package substrate. An integrated heat spreader (IHS) may be coupled with the STIM such that the STIM is between the IHS and the die, and the IHS may include a feature that is to control bleed-out of the STIM during STIM reflow based on surface tension of the STIM. Other embodiments may be described or claimed.

Embodiments of the disclosure relate to an MIO substrate with integrated jet cooling for electronic modules and a method of forming the same. In one embodiment, a substrate for an electronic module includes a thermal compensation base layer having an MIO structure and a cap layer overgrown on the MIO structure. A plurality of orifices extends through the thermal compensation base layer between an inlet face and an outlet face positioned opposite to the inlet face, defining a plurality of jet paths. A plurality of integrated posts extends outward from the cap layer, wherein each integrated post of the plurality of integrated posts is positioned on the outlet face between each orifice of the plurality of orifices.

Disclosed is a method that includes: providing semiconductor dies, each of the semiconductor dies having a thinner active region surrounded by a thicker inactive region so that each of the semiconductor dies has a first cavity vertically aligned with the thinner active region and laterally surrounded by the thicker inactive region; providing a metal carrier having connection parts secured to the metal carrier, each of the connection parts dimensioned to fit within the first cavity of one of the semiconductor dies; inserting each of the connection parts of the metal carrier into the respective first cavity of the corresponding semiconductor die; after the inserting, attaching the metal carrier to the semiconductor dies; and after the attaching, singulating the metal carrier so that each of the connection parts of the metal carrier remains attached to the corresponding semiconductor die.

A method of and system for adhesive bonding by a) providing a polymerizable adhesive composition on a surface of an element to be bonded to form an assembly; b) irradiating the assembly with radiation at a first wavelength capable of vulcanization of bonds in the polymerizable adhesive composition by activation of sulfur-containing compound with at least one selected from x-ray, e-beam, visible, or infrared light to thereby generate ultraviolet light in the polymerizable adhesive composition; and c) adhesively joining two or more components together by way of the polymerizable adhesive composition, and a curable polymer for use therein.

A semiconductor device according to the present invention includes a semiconductor chip having a semiconductor layer that has a first surface on a die-bonding side, a second surface on the opposite side of the first surface, and an end surface extending in a direction crossing the first surface and the second surface, a first electrode that is formed on the first surface and has a peripheral edge at a position separated inward from the end surface, and a second electrode formed on the second surface, a conductive substrate onto which the semiconductor chip is die-bonded, a conductive spacer that has a planar area smaller than that of the first electrode and supports the semiconductor chip on the conductive substrate, and a resin package that seals at least the semiconductor chip and the conductive spacer.

Methods of manufacturing semiconductor packages. Implementations may include: providing a substrate with a first side, a second side, and a thickness; forming a plurality of pads on the first side of the substrate; and applying die attach material to the plurality of pads. The method may include bonding a wafer including a plurality of semiconductor die to the substrate at one or more die pads included in each die. The method may also include singulating the plurality of semiconductor die, overmolding the plurality of semiconductor die and the first side of the substrate with an overmold material, and removing the substrate to expose the plurality of pads and to form a plurality of semiconductor packages coupled together through the overmold material. The method also may include singulating the plurality of semiconductor packages to separate them.

Methods of manufacturing semiconductor packages. Implementations may include: providing a substrate with a first side, a second side, and a thickness; forming a plurality of pads on the first side of the substrate; and applying die attach material to the plurality of pads. The method may include bonding a wafer including a plurality of semiconductor die to the substrate at one or more die pads included in each die. The method may also include singulating the plurality of semiconductor die, overmolding the plurality of semiconductor die and the first side of the substrate with an overmold material, and removing the substrate to expose the plurality of pads and to form a plurality of semiconductor packages coupled together through the overmold material. The method also may include singulating the plurality of semiconductor packages to separate them.

A semiconductor arrangement includes a semiconductor substrate having a dielectric insulation layer and at least a first metallization layer arranged on a first side of the dielectric insulation layer. The first metallization layer includes at least two sections, each section being separated from a neighboring section by a recess. A semiconductor body is arranged on one of the sections of the first metallization layer. At least one indentation is arranged between a first side of the semiconductor body and a closest edge of the respective section of the first metallization layer. A distance between the first side and the closest edge of the section of the first metallization layer is between 0.5 mm and 5 mm.

A power module includes an upper substrate comprising a plurality of circuit pattern areas made of a metal and a dielectric area disposed between each of the plurality of circuit pattern areas; a lower substrate including a plurality of circuit pattern areas made of a metal and a dielectric area disposed between each of the plurality of circuit pattern areas; and a semiconductor element having an upper terminal and a lower terminal, the upper terminal and the lower terminal being bonded to a lower surface of the upper substrate and an upper surface of the lower substrate, respectively.