In a described example, an apparatus includes: a metal leadframe including a dielectric die support formed in a central portion of the leadframe, and having metal leads extending from the central portion, portions of the metal leads extending into the central portion contacted by the dielectric die support; die attach material over the dielectric die support; a semiconductor die mounted to the dielectric die support by the die attach material, the semiconductor die having bond pads on a device side surface facing away from the dielectric die support; electrical connections extending from the bond pads to metal leads of the leadframe; and mold compound covering the semiconductor die, the electrical connections, the dielectric die support, and portions of the metal leads, the mold compound forming a package body.

An interconnected semicondcutor subassembly structure and formation thereof. The interconnected semicondcutor subassembly structure includes an interconnect structure, and first and second semicondcutor dies bonded to respective portions of a top surface of the interconnect structure. The interconnected semicondcutor subassembly structure further includes an underfill layer formed within a first gap located between a bottom surface of the first semiconductor die and the first portion the top surface of the interconnect structure, formed within a second gap located between the bottom surface of the second semiconductor die and the second portion of the top surface of the interconnect structure, and formed within a first portion of a third gap located between the first semicondcutor die and the second semicondcutor die. A top surface of the underfill layer formed within the first portion of the third gap located between the first and second semicondcutor dies has a concave meniscus shape.

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.

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.

A semiconductor device has a leadframe and a first electrical component disposed over the leadframe. A clip bond is disposed over the first electrical component. The clip bond has a plurality of recesses each having a different depth. A first recess is proximate to a first distal end of the first electrical component, and a second recess is proximate to a second distal end of the first electrical component opposite the first distal end of the first electrical component. A depth of the first recess is different from a depth of the second recess. A third recess is over a surface of the first electrical component. A depth of the third recess is different from the depth of the first recess and the depth of the second recess. A second electrical component is disposed over the leadframe. The clip bond extends over the second electrical component.

A semiconductor device includes: a first semiconductor chip mounted on a chip mounting portion via a first bonding material; and a second semiconductor chip mounted on the first semiconductor chip via a second bonding material. The first semiconductor chip includes: a protective film; and a first pad electrode exposed from the protective film in a first opening portion of the protective film. The second semiconductor chip is mounted on the first pad electrode of the first semiconductor chip via the second bonding material. The second bonding material includes: a first member being in contact with the first pad electrode; and a second member interposed between the first member and the second semiconductor chip. The first member is a conductive bonding material of a film shape, and the second member is an insulating bonding material of a film shape.

A semiconductor packaging device includes a packaging module, a heat dissipation cover and a thermal interface material layer. The package module includes a substrate, and a working chip mounted on the substrate. The heat dissipation cover includes a metal cover fixed on the substrate and covering the working chip, an accommodating recess located on the metal cover to accommodate the working chip, and a plurality of protrusive columns respectively formed on the metal cover and distributed within the accommodating recess at intervals. The depth of the accommodating recess is greater than the height of each protrusive column, and the accommodating recess is greater than the working chip. The thermal interface material layer is non-solid, and located within the accommodating recess between the protrusive columns to wrap the protrusive columns and contact with the working chip, the metal cover and the protrusive columns.

A semiconductor package includes a die stack including a first semiconductor die having a first interconnect structure, and a second semiconductor die having a second interconnect structure direct bonding to the first interconnect structure of the first semiconductor die. The second interconnect structure includes connecting pads disposed in a peripheral region around the first semiconductor die. First connecting elements are disposed on the connecting pads, respectively. A substrate includes second connecting elements on a mounting surface of the substrate. The first connecting elements are electrically connected to the second connecting elements through an anisotropic conductive structure.

A method of manufacturing a semiconductor device is provided. The method includes forming a package leadframe including a die pad, a first ridge formed at a first outer edge of the die pad, a second ridge formed at a second outer edge of the die pad opposite of the first outer edge and separate from the first ridge, and a plurality of leads surrounding the die pad. A semiconductor die is attached to the die pad by way of a die attach material. The semiconductor die is located on the die pad between the first ridge and the second ridge. An encapsulant encapsulates the semiconductor die and at least a portion of the package leadframe.