A structure includes a circuit substrate, a device, a metal layer, a lid and a thermal interface material layer. The device is disposed on and electrically connected to the circuit substrate. The device includes at least one semiconductor die laterally encapsulated by an insulating encapsulation. The metal layer is covering a back surface of the at least one semiconductor die and the insulating encapsulation. The lid is disposed on the circuit substrate, and the lid is adhered to the metal layer through the thermal interface material layer.

An electronic package and a manufacturing method thereof, which embeds an electronic structure acting as an auxiliary functional component and a plurality of conductive pillars in an encapsulation layer, and disposes an electronic component on the encapsulation layer, so as to facilitate electrical transmission with the electronic component in a close range.

A semiconductor device includes: a first semiconductor element having a first electrode on a main surface side thereof and a second electrode on a back surface side thereof; a base material provided with a connection conductor connected to the first electrode; a sealing resin provided on the base material to seal the first semiconductor element; and a first via provided in the sealing resin and electrically connected to the second electrode of the first semiconductor element.

A method includes bonding a first device die with a second device die. The second device die is over the first device die. A passive device is formed in a combined structure including the first and the second device dies. The passive device includes a first and a second end. A gap-filling material is formed over the first device die, with the gap-filling material including portions on opposite sides of the second device die. The method further includes performing a planarization to reveal the second device die, with a remaining portion of the gap-filling material forming an isolation region, forming a first and a second through-vias penetrating through the isolation region to electrically couple to the first device die, and forming a first and a second electrical connectors electrically coupling to the first end and the second end of the passive device.

In an embodiment, a structure includes: a first integrated circuit die including first die connectors; a first dielectric layer on the first die connectors; first conductive vias extending through the first dielectric layer, the first conductive vias connected to a first subset of the first die connectors; a second integrated circuit die bonded to a second subset of the first die connectors with first reflowable connectors; a first encapsulant surrounding the second integrated circuit die and the first conductive vias, the first encapsulant and the first integrated circuit die being laterally coterminous; second conductive vias adjacent the first integrated circuit die; a second encapsulant surrounding the second conductive vias, the first encapsulant, and the first integrated circuit die; and a first redistribution structure including first redistribution lines, the first redistribution lines connected to the first conductive vias and the second conductive vias.

Provided is a module which has a package-on-package structure including a redistribution layer and can be easily reduced in height. A module 1 includes an upper module including a substrate, a first component, and a sealing resin layer, and a lower module including an intermediate layer and a redistribution layer. The first component is connected to the redistribution layer with a columnar conductor interposed therebetween and provided in the intermediate layer, and both the first component and a second component are rewired by the redistribution layer. Since the intermediate layer is formed by using a frame-shaped substrate, the upper module and the lower module can be connected without necessarily a bump, so that it is possible to provide a module which has a fanout-type package-on-package structure and can be easily reduced in height.

A multi-chip package includes: a first semiconductor integrated-circuit (IC) chip; a second semiconductor integrated-circuit (IC) chip over and bonded to the first semiconductor integrated-circuit (IC) chip; a plurality of first metal posts over and coupling to the first semiconductor integrated-circuit (IC) chip, wherein the plurality of first metal posts are in a space beyond and extending from a sidewall of the second semiconductor integrated-circuit (IC) chip; and a first polymer layer over the first semiconductor integrated-circuit (IC) chip and in the space, wherein the plurality of first metal posts are in the first polymer layer, wherein a top surface of the first polymer layer, a top surface of the second semiconductor integrated-circuit (IC) chip and a top surface of each of the plurality of first metal posts are coplanar.

A method of fabricating a semiconductor package structure is provided. The structure is configured to include a base substrate, a die placed on the base substrate, the die including a semiconductor device, a solder bump placed on one surface of the die to exhaust heat generated in the die to an outside; and a solder ball placed on other surface of the die facing the one surface to transmit a signal, which is produced by the semiconductor device of the die, to an external device.

Presented herein is a WLCSP intermediate structure and method forming the same, the method comprising forming a first redistribution layer (RDL) on a carrier, the first RDL having mounting pads disposed on the first RDL, and mounting interposer dies on a second side of the first RDL. A second RDL is formed over a second side of the interposer dies, the second RDL having a first side adjacent to the interposer dies, one or more lands disposed on the second RDL, at least one of the one or more lands in electrical contact with at least one of the interposer dies or at least one of the mounting pads. A molding compound is formed around the interposer dies and over a portion of the first RDL prior to the forming the second RDL and the second RDL is formed over at least a portion of the molding compound.

Microelectronic assemblies, and related devices and methods, are disclosed herein. For example, in some embodiments, a microelectronic assembly may include a package substrate including a dielectric material having a first surface and an opposing second surface, a first photodefinable material on at least a portion of the second surface, and a second photodefinable material on at least a portion of the first photodefinable material, wherein the second photodefinable material has a different material composition than the first photodefinable material.