In one example, a semiconductor device comprises a first base substrate comprising a first base conductive structure, a first encapsulant contacting a lateral side of the first base substrate, a redistribution structure (RDS) substrate over the base substrate and comprising an RDS conductive structure coupled with the first base conductive structure, a first electronic component over the RDS substrate and over a first component terminal coupled with the RDS conductive structure, and a second encapsulant over the RDS substrate and contacting a lateral side of the first electronic component. Other examples and related methods are also disclosed herein.

Multiple (multi-) die integrated circuit (IC) packages for supporting higher connection density, and related fabrication methods. The multi-die IC package includes split dies that provided in respective die packages that are stacked on top of each other to conserve package area. To support signal routing, including through-package signal routing that extends through the die package, each die package includes vertical interconnects disposed adjacent to their respective dies and coupled to a respective package substrate (and interposer substrate if provided) in the package substrate. In this manner, as an example, through-silicon-vias (TSVs) are not required to be fabricated in the multi-die IC package that extend through the dies themselves to provide signal routing between the respective die packages. In another example, space created between adjacent interposer substrates of stacked die packages, as stood off from each other through the interconnect bumps, provides an area for heat dissipation.

A manufacturing method of a semiconductor package includes the following steps. A chip is provided. The chip has an active surface and a rear surface opposite to the active surface. The chip includes conductive pads disposed at the active surface. A first solder-containing alloy layer is formed on the rear surface of the chip. A second solder-containing alloy layer is formed on a surface and at a location where the chip is to be attached. The chip is mounted to the surface and the first solder-containing alloy layer is aligned with the second solder-containing alloy layer. A reflow step is performed on the first and second solder-containing alloy layers to form a joint alloy layer between the chip and the surface.

Disclosed is a semiconductor package comprising a package substrate, an interposer substrate on the package substrate and including a first redistribution substrate, a second redistribution substrate on a bottom surface of the first redistribution substrate, and an interposer molding layer between the first redistribution substrate and the second redistribution substrate, a connection substrate on the interposer substrate and having a connection hole that penetrates the connection substrate, a first semiconductor chip on the interposer substrate and in the connection hole, a second semiconductor chip on the interposer substrate, in the connection hole and horizontally spaced apart from the first semiconductor chip, and a connection semiconductor chip in the interposer molding layer and on the bottom surface of the first redistribution substrate.

An interconnect for a semiconductor device includes a laminate substrate; a first plurality of electrical devices in or on a surface of the laminate substrate; a redistribution layer having a surface disposed on the surface of the laminate substrate; a second plurality of electrical devices in or on the surface of the redistribution layer; and a plurality of transmission lines between the first plurality of electrical devices and the second plurality of electrical devices. The surface of the laminate substrate and the surface of the redistribution layer are parallel to each other to form a dielectric structure and a conductor structure.

Disclosed is a micro light-emitting component, a micro light-emitting diode, and a transfer layer. The transfer layer has a recess for receiving the micro light-emitting diode to permit the micro light-emitting diode to be retained by the transfer layer, and is transformable from a first state, in which the transfer layer is deformed by the micro light-emitting diode to form the recess, to a second state, in which the micro light-emitting diode received in the recess is retained by the transfer layer. Also disclosed are micro light-emitting component matrix and a method for manufacturing the micro light-emitting component matrix.

A package structure and method of forming the same are provided. The package structure includes a first die and a second die disposed side by side, a first encapsulant laterally encapsulating the first and second dies, a bridge die disposed over and connected to the first and second dies, and a second encapsulant. The bridge die includes a semiconductor substrate, a conductive via and an encapsulant layer. The semiconductor substrate has a through substrate via embedded therein. The conductive via is disposed over a back side of the semiconductor substrate and electrically connected to the through substrate via. The encapsulant layer is disposed over the back side of the semiconductor substrate and laterally encapsulates the conductive via. The second encapsulant is disposed over the first encapsulant and laterally encapsulates the bridge die.

A semiconductor device includes a semiconductor element, an internal electrode connected to the semiconductor element, a sealing resin covering the semiconductor element and a portion of the internal electrode, and an external electrode exposed from the sealing resin and connected to the internal electrode. The internal electrode includes a wiring layer and a columnar portion, where the wiring layer has a wiring layer front surface facing the back surface of the semiconductor element and a wiring layer back surface facing opposite from the wiring layer front surface in the thickness direction. The columnar portion protrudes in the thickness direction from the wiring layer front surface. The columnar portion has an exposed side surface facing in a direction perpendicular to the thickness direction. The external electrode includes a first cover portion covering the exposed side surface.

A semiconductor package includes a first semiconductor chip on a package substrate, a second semiconductor chip on the first semiconductor chip and having a redistribution layer on a bottom surface thereof, under-bump pads on a bottom surface of the redistribution layer, first solders adjacent to the first semiconductor chip and connecting first pads of the under-bump pads to substrate pads of the package substrate, and a molding layer on the package substrate and covering the first and second semiconductor chips and the first solders. Second pads of the under-bump pads are in direct contact with a top surface of the first semiconductor chip. The first pads are connected through the redistribution layer to an integrated circuit of the second semiconductor chip. The second pads are insulated from the integrated circuit of the second semiconductor chip.

The present disclosure provides a package device including a conductive pad, a protecting block, and a redistribution layer. The protecting block is disposed on the conductive pad. The redistribution layer is disposed on the protecting block, and the conductive pad is electrically connected to the redistribution layer through the protecting block.