A method of manufacturing a packaged semiconductor device includes forming an assembly by placing a semiconductor die over a substrate with a die attach material between the semiconductor die and the substrate. A conformal structure which includes a pressure transmissive material contacts at least a portion of a top surface of the semiconductor die. A pressure is applied to the conformal structure and in turn, the pressure is transmitted to the top surface of the semiconductor die by the pressure transmissive material. While the pressure is applied, concurrently encapsulating the assembly with a molding compound and exposing the assembly to a temperature that is sufficient to cause the die attach material to sinter.

A method of manufacturing a semiconductor device may include forming an adhesive film on a surface of a semiconductor chip, mounting the semiconductor chip on a substrate such that the adhesive film contacts an upper surface of the substrate, and bonding the semiconductor chip and the substrate curing the adhesive film by simultaneously performing a thermo-compression process and an ultraviolet irradiation process on the adhesive film disposed between the substrate and the semiconductor chip.

In a method of manufacturing a biomimetic highly stretchable conductive dry adhesive patch, a mold including a plurality of holes is provided by etching a semiconductor substrate including an insulation layer based on a footing effect. A conductive polymer composite is provided by dispersing mixed conductive fillers in a liquid elastomer. The mixed conductive fillers are formed by mixing one-dimensional conductive fillers and two-dimensional conductive fillers. The conductive polymer composite is applied on the mold such that the conductive polymer composite is injected into the plurality of holes. A conductive dry adhesive structure including a plurality of micropillars corresponding to the plurality of holes is obtained by performing a post-treatment on the conductive polymer composite applied on the mold and by removing the mold. Each of the plurality of micropillars includes a body portion and a tip portion. The tip portion has a spatula shape, is formed on the body portion, and has an area larger than that of the body portion in a plan view.

A method of fabricating a semiconductor package structure is provided. The method includes applying a plurality of first adhesive portions onto a carrier; applying a second adhesive portion onto the carrier; disposing a plurality of micro pins respectively in the first adhesive portions, such that each of the micro pins has a first portion embedded in a corresponding one of the first adhesive portions and a second portion protruding from said corresponding one of the first adhesive portions; bonding a die to the second adhesive portion; forming a molding compound surrounding the micro pins and the die; and removing the carrier from the molding compound after forming the molding compound.

A semiconductor package structure includes a molding compound, a micro pin extending through the molding compound, and a die surrounded by the molding compound. The micro pin has a top surface, a bottom surface, and a sidewall extending from the bottom surface to the top surface of the micro pin. The sidewall of the micro pin has a first portion and a second portion. The first portion of the sidewall is adjacent to the bottom surface of the micro pin and free of the molding compound. The second portion of the sidewall is adjacent to the top surface of the micro pin and in contact with the molding compound.

Edge interconnects for interconnecting solar cells are disclosed. The edge interconnects include a layer of an electrically conductive adhesive overlying an insulating dielectric layer applied to edge of a solar cell and electrically interconnected to a busbar. Solar cell modules include adjacent solar cells comprising edge interconnects interconnected using an interconnection element. An interconnection element can be a solder paste or a solder containing electrically conductive ribbon. Methods of forming solar cell edge interconnects include applying an insulating dielectric coating to edges of a solar cell, depositing a busbar in proximity to the insulated edges of the solar cell, depositing an electrically conductive adhesive over at least portion of the busbar an over at least a portion of the dielectric layer. Solar cell modules can be formed by interconnecting adjacent solar cells using an interconnection element.

A method includes applying a die attach material to a die pad of an integrated circuit package. The die attach material is employed as a bonding material to the die pad. The method includes mounting an integrated circuit die to the die pad of the integrated circuit via the die attach material. The method includes printing an adhesion deposition material on the die attach material appearing at the interface of the integrated circuit die and the die pad of the integrated circuit package to mitigate delamination between the integrated circuit die and the die pad.

A dual side cooling power module includes: a lower substrate including a recessed portion on at least one surface thereof, a semiconductor chip formed in the recessed portion, lead frames formed at both ends of the lower substrate, and an upper substrate formed on the semiconductor chip, a portion of the lead frames, and the lower substrate.

A semiconductor package includes a carrier, at least and adhesive portion, a plurality of micro pins and a die. The carrier has a first surface and second surface opposite to the first surface. The adhesive portion is disposed on the first surface, and the plurality of the micro pins is disposed in the adhesive portions. The die is disposed on the remaining adhesive portion free of the micro pins.

A method of attaching a semiconductor chip on a lead frame includes A) providing a semiconductor chip, B) applying a solder metal layer sequence to the semiconductor chip, wherein the solder metal layer sequence includes a first metallic layer including indium or an indium-tin alloy, C) providing a lead frame, D) applying a metallization layer sequence to the lead frame, wherein the metallization layer sequence includes a fourth layer including indium and/or tin arranged above the lead frame and a third layer including gold arranged above the fourth layer, E) forming an intermetallic intermediate layer including gold and indium, gold and tin or gold, tin and indium, G) applying the semiconductor chip to the lead frame via the solder metal layer sequence and the intermetallic intermediate layer, and H) heating the arrangement produced in G) to attach the semiconductor chip to the lead frame.