A semiconductor module that can absorb thermal stress, and a manufacturing method therefor are provided. A semiconductor module includes a film interposer that includes a plurality of through electrodes which run in the thickness direction; a logic chip that is disposed on one surface side of the film interposer, and is connected electrically to the through electrodes; and a RAM unit that is a RAM module disposed on the other surface side of the film interposer, and connected electrically to the logic chip via the through electrodes.

Achieving homogeneous and heterogeneous integration for 2.5D and 3D integrated circuit, chip-to-wafer, chip-to-substrate, or wafer-to-wafer bonding is an essential technology. The landing wafer or substrate is bonded with a carrier by using a temporary bonding material before thinning the landing wafer to the desired thickness. Upon completion of redistribution layer formation, Cu pad formation, or other backside processing, dies or wafers with through-silicon vias are stacked onto the landing substrate before molding and singulation. As the landing wafer usually has interconnection metals in the bond line, and those interconnection metals are typically made from lead-free solder alloys, deformation of those solder alloys during thermocompression bonding becomes an issue for manufacturers. To address this issue, a polymeric material with desired strengths is coated on the device wafer to form a conformal protective layer on top of solder alloys, thus enabling temporary bonding and debonding processes.

The application provides a semiconductor packaging structure, a semiconductor packaging method, a semiconductor packaging device and an electronic product. The semiconductor packaging structure comprises a substrate, at least one packaged component, a redistribution layer and a passivation layer. The substrate has at least one groove and the at least one packaged component is fixed in the at least one groove in one-to-one correspondence. Each packaged component is separated from a corresponding groove, in which the package component is disposed, by insulating materials. The at least one packaged component has first bonding pads on at least one active surface facing away from the substrate and are flush. The redistribution layer is formed using wafer fabrication process over the at least one active surface. The substrate includes a semiconductor material or insulating material with a thermal expansion coefficient that is the same as or similar to that of a base semiconductor material in the packaged component.

Disclosed herein are microelectronic assemblies with integrated perovskite layers, and related devices and methods. For example, in some embodiments, a microelectronic assembly may include an organic package substrate portion having a surface with a conductive layer, and a perovskite conductive layer on the conductive layer. In some embodiments, a microelectronic assembly may include an organic package substrate portion having a surface with a conductive layer, a perovskite conductive layer having a first crystalline structure on the conductive layer, and a perovskite dielectric layer having a second crystalline structure on the perovskite conductive layer. In some embodiments, the first and second crystalline structures have a same orientation.

A method of forming a chip package is provided. The method includes providing a malleable carrier with a layer of an electrically conductive material formed thereon, and positive fitting the malleable carrier to a chip to at least partially enclose the chip with the malleable carrier. The layer at least partially physically contacts the chip, such that the layer electrically contacts a chip contact of the chip. The layer forms a redistribution layer.

A semiconductor device includes a substrate, semiconductor dies on the substrate, molding compound and reinforcing blocks on the substrate. The reinforcing blocks may be provided at positions on the substrate where mechanical stresses develop in the device during singulation, such as at curves and/or discontinuous points around the outline of the substrate, to add strength to the substrate.

Electronic assembly methods and structures are described. In an embodiment, an electronic assembly method includes bringing together an electronic component and a routing substrate, and directing a large area photonic soldering light pulse toward the electronic component to bond the electronic component to the routing substrate.

Semiconductor assemblies including thermal management configurations for reducing heat transfer between overlapping devices and associated systems and methods are disclosed herein. A semiconductor assembly may comprise a first device and a second device with a thermally conductive layer, a thermal-insulator interposer, or a combination thereof disposed between the first and second devices. The thermally conductive layer and/or the thermal-insulator interposer may be configured to reduce heat transfer between the first and second devices.

Semiconductor assemblies including thermal management configurations for reducing heat transfer between overlapping devices and associated systems and methods are disclosed herein. A semiconductor assembly may comprise a first device and a second device with a thermally conductive layer, a thermal-insulator interposer, or a combination thereof disposed between the first and second devices. The thermally conductive layer and/or the thermal-insulator interposer may be configured to reduce heat transfer between the first and second devices.

Electronic assembly methods and structures are described. In an embodiment, an electronic assembly method includes bringing together an electronic component and a routing substrate, and directing a large area photonic soldering light pulse toward the electronic component to bond the electronic component to the routing substrate.