A package is disclosed. In one example, the package comprises a substrate having at least one first recess on a front side and at least one second recess on a back side, wherein the substrate is separated into a plurality of separate substrate sections by the at least one first recess and the at least one second recess, an electronic component mounted on the front side of the substrate, and a single encapsulant filling at least part of the at least one first recess and at least part of the at least one second recess. The encapsulant fully circumferentially surrounds sidewalls of at least one of the substrate sections.

A fan-out packaging method includes: prepare circuit patterns on one side or both sides of a substrate; install electronic parts on one side or both sides of the substrate; prepare packaging layers on both sides of the substrate; the packaging layers on both sides of the substrate package the substrate, the circuit patterns, and the electronic parts, the packaging layers being made of a thermal-plastic material; wherein the substrate is provided with a via hole; both sides of the substrate are communicated by means of the via hole; a part of the packaging layers penetrate through the via hole when the packaging layers are prepared on both sides of the substrate; and the packaging layers on both sides of the substrate are connected by means of the via hole.

A semiconductor device includes an insulating layer having a first surface and a second surface opposite to the first surface. The semiconductor device includes at least one semiconductor element located on a side of the first surface. The semiconductor device includes a first metal sinter and a second metal sinter. The first metal sinter is in contact with the first surface of the insulating layer and the semiconductor element, and bonds the insulating layer and the semiconductor element. The second metal sinter is in contact with the second surface of the insulating layer.

Disclosed is a semiconductor package comprising a first chip stack including on a substrate a plurality of first semiconductor chips in an offset stack structure and stacked to expose a connection region at a top surface of each of the first semiconductor chips, a second semiconductor chip on the substrate and horizontally spaced apart from the first chip stack, a spacer on the second semiconductor chip, and a second chip stack including third semiconductor chips in an offset stack structure on the first chip stack and the spacer. Each of the first semiconductor chips includes a first chip pad on the connection region and a first wire that extends between the first chip pad and the substrate. The first wire of an uppermost one of the first semiconductor chips is horizontally spaced apart from a lowermost one of the third semiconductor chips.

Structures and formation methods of a chip package are provided. The chip package includes a semiconductor die having a conductive element and an antenna element over the semiconductor die. The chip package also includes a first conductive feature electrically connecting the conductive element of the semiconductor die and the antenna element. The chip package further includes a protective layer surrounding the first conductive feature. In addition, the chip package includes a second conductive feature over the first conductive feature. A portion of the second conductive feature is between the first conductive feature and the protective layer.

The disclosure provides an electronic device and a manufacturing method thereof. The electronic device includes a substrate, an electronic element, an underfill layer, and a protective structure. The electronic element is disposed on the substrate. At least a portion of the underfill layer is disposed between the substrate and the electronic element. A thickness of the underfill layer is not greater than a height from a surface of the substrate to an upper surface of the electronic element. The protective structure is disposed on the substrate and adjacent to the underfill layer. The electronic device and the manufacturing method thereof of the disclosure may effectively control an area of the underfill layer.

A power module for PCB embedding includes: a leadframe; a power semiconductor die with a first load terminal and control terminal at a first side of the die and a second load terminal at the opposite side, the second load terminal soldered to the leadframe; a first metal clip soldered to the first load terminal and forming a first terminal of the power module at a first side of the power module; and a second metal clip soldered to the control terminal and forming a second terminal of the power module at the first side of the power module. The leadframe forms a third terminal of the power module at the first side of the power module, or a third metal clip is soldered to the leadframe and forms the third terminal. The power module terminals are coplanar within +/−30 μm at the first side of the power module.

A method includes forming multiple photonic devices in a semiconductor wafer, forming a v-shaped groove in a first side of the semiconductor wafer, forming an opening extending through the semiconductor wafer, forming multiple conductive features within the opening, wherein the conductive features extend from the first side of the semiconductor wafer to a second side of the semiconductor wafer, forming a polymer material over the v-shaped groove, depositing a molding material within the opening, wherein the multiple conductive features are separated by the molding material, after depositing the molding material, removing the polymer material to expose the v-shaped groove, and placing an optical fiber within the v-shaped groove.

The present disclosure is directed to a leadframe having a recess in a body of the leadframe to collect glue overflowing from the manufacturing process of coupling a semiconductor die to the leadframe. The recess extends beneath an edge of the semiconductor die so that any tendency of the glue to adhere to the semiconductor die is counteracted by a tendency of the glue to adhere to a wall of the recess and at least partially fill the volume of the recess. In addition, the recess for collecting adhesive may also form a mold lock on an edge of the leadframe, the mold lock providing a more durable connection between the leadframe and an encapsulant during physical and temperature stresses.

A power module is obtained in which the thermal resistance in the range from a semiconductor device to a base plate is reduced and the stress in the joining portion is relieved. The power module includes at least one semiconductor device, an insulating substrate having an insulating layer, a circuit layer provided on an upper surface of the insulating layer and a metal layer provided on a lower surface of the insulating layer, and a sintering joining member with an upper surface larger in outer circumference than a back surface of the at least one semiconductor device, to join together the back surface of the at least one semiconductor device and an upper surface of the circuit layer on an upper-surface side of the insulating layer.