A semiconductor device includes: a semiconductor element; and a first conductor and a second conductor respectively joined to a first surface and a second surface of the semiconductor element via Sn-based solder, in which a Ni-based plated layer is formed on surfaces of the first conductor and the second conductor that oppose the Sn-based solder and on the first surface and the second surface of the semiconductor element, and an interface reaction inhibition layer made of (Cu, Ni).sub.6Sn.sub.5 and having a layer thickness of 1.2 to 4.0 m is formed at an interface between the Ni-based plated layer and the Sn-based solder.

Provided is a flux that can suppress the generation of voids when an indium alloy sheet is used to perform a continuous reflow under different temperature conditions. The present invention employs a flux that contains a rosin ester, an organic acid (A), and a solvent (S). The organic acid (A) includes a dimer acid (A1) that demonstrates a weight reduction rate of not more than 1 mass % in a thermogravimetric analysis in which the dimer acid is heated up to 260 C. at a temperature rising rate of 10 C./min. The solvent (S) includes a solvent (S1) that demonstrates the weight reduction rate of at least 99 mass % in a thermogravimetric analysis in which the solvent (S1) is heated up to 150 C. at a temperature rising rate of 6 C./min.

A chip package assembly includes a first high-power chip, a second low-power chip, a thermal cooling device and a heterogeneous thermal interface material (HTIM). The thermal cooling device may overlie the first chip and the second chip. The HTIM includes a first thermal interface material (TIM) and a second TIM. The first TIM overlies the first chip, and the second TIM overlies the second chip. The first TIM includes a material that has a first thermal conductivity and a first modulus of elasticity. The first TIM can reflow when the first die reaches a first TIM reflow temperature. The second TIM comprises at least a polymer material. The second TIM has a second modulus of elasticity that is greater than the first modulus of elasticity and a second thermal conductivity that is less than the first thermal conductivity.

A method of repairing a display panel and a repaired display panel are provided. The display panel includes a panel substrate, a plurality of micro LEDs arranged on the panel substrate, and a molding member covering the plurality of micro LEDs. The molding member includes a first molding member and a second molding member disposed in a region surrounded by the first molding member. The second molding member has a composition or a shape different from that of the first molding member, and the second molding member surrounds at least one side surface of the plurality of micro LEDs.

Implementations of a semiconductor package may include two or more die, each of the two more die coupled to a metal layer at a drain of each of the two more die, the two or more die and each metal layer arranged in two parallel planes; a first interconnect layer coupled at a source of each of the two more die; a second interconnect layer coupled to a gate of each of the two or more die and to a gate package contact through one or more vias; and an encapsulant that encapsulates the two or more die and at least a portion of the first interconnect layer, each metal layer, and the second interconnect layer.

A thermal conduction sheet holder include, in the following order, an elongated carrier film, a plurality of thermal conduction sheets, and an elongated cover film covering the plurality of thermal conduction sheets, the shortest distance between adjacent thermal conduction sheets is 2 mm or more, the plurality of thermal conduction sheets are disposed at intervals in a longitudinal direction of the carrier film and the cover film, and the plurality of thermal conduction sheets are peelable from the cover film and the carrier film.

Provided herein is a method for producing a die attach adhesive film sheet, comprising: Providing a first release substrate layer, a die attach adhesive layer, and a dicing tape layer, and joining the first release substrate layer, the die attach adhesive layer, and the dicing tape layer in that order to form a multi-layer structure; Working the multi-layer structure to form a circular preformed die attach adhesive film sheet, wherein during said working the first release substrate receives a z-directional indentation therein; and Removing the first release substrate with the z-directional indentation therein from the die attach adhesive layer, and placing in its stead a second release substrate in contact with the die attach adhesive layer.

An electronic package is provided, where a laterally diffused metal oxide semiconductor (LDMOS) type electronic structure is mounted onto a complementary metal oxide semiconductor (CMOS) type electronic element to be integrated into a chip module, thereby shortening electrical transmission path between the electronic structure and the electronic element so as to reduce the communication time between the electronic structure and the electronic element.

According to one embodiment, a semiconductor device includes: a first frame; a first chip on the first frame; a second frame spaced apart from the first frame in a first direction; a second chip on the second frame; and a first joint terminal above the second chip. The first frame includes a first terminal portion extending toward the second frame. The first joint terminal includes a second terminal portion extending toward the first frame. The second terminal portion includes first and second projecting portions each of which projects toward the first frame and which are spaced apart from each other in a second direction. An end portion of the first projecting portion and an end portion of the second projecting portion are each joined on the first terminal portion.

Disclosed embodiments provide light-emitting diodes (LEDs) and interconnect structures that employ particularly shaped electrodes and a conductive metal-based adhesive that are selected to provide a flexible, robust interconnect that is capable of resisting lateral shear forces, while maintaining a low bond process temperature that is process compatible with other LED component materials. In a non-limiting aspect, disclosed embodiments employ a barrier coating on the interconnect or bonding materials comprising a conductive metal-based adhesive to inhibit moisture and air contact with the conductive metal-based adhesive, thereby preventing or mitigating migration of metal ions in the conductive metal-based adhesive in operation.