Microelectronic assemblies, and related devices and methods, are disclosed herein. For example, in some embodiments, a microelectronic assembly may include a package substrate having a first surface and an opposing second surface; a radio frequency (RF) die having a lateral surface area and a plurality of contacts on a face, where the RF die is embedded in the package substrate with the plurality of contacts facing towards the second surface of the package substrate, and an RF front end between the RF die and the first surface of the package substrate, where the RF front end is positioned under the RF die and does not extend beyond the lateral surface area of the RF die.

A method includes forming a polymer layer covering a metal via in a wafer, grooving the wafer to form a trench, wherein the trench extends from a top surface of the polymer layer into the wafer, and performing a die-saw on the wafer to separate the wafer into a plurality of device dies. A kerf passes through the trench. One of the device dies is placed over a carrier. An encapsulating material is dispensed over and around the device die. The method further includes pressing and curing the encapsulating material. After the encapsulating material is cured, a sidewall of the polymer layer is tilted. A planarization is performed on the encapsulating material until the polymer layer and the metal via are exposed. A redistribution line is formed over and electrically coupled to the metal via.

Methods/structures of forming in-package inductor structures are described. Embodiments include a substrate including a dielectric material, the substrate having a first side and a second side. A conductive trace is located within the dielectric material. A first layer is on a first side of the conductive trace, wherein the first layer comprises an electroplated magnetic material, and wherein a sidewall of the first layer is adjacent the dielectric material. A second layer is on a second side of the conductive trace, wherein the second layer comprises the electroplated magnetic material, and wherein a sidewall of the second layer is adjacent the dielectric material.

A semiconductor package includes a cavity substrate, a semiconductor die, and an encapsulant. The cavity substrate includes a redistribution structure and a cavity layer on an upper surface of the redistribution structure. The redistribution structure includes pads on the upper surface, a lower surface, and sidewalls adjacent the upper surface and the lower surface. The cavity layer includes an upper surface, a lower surface, sidewalls adjacent the upper surface and the lower surface, and a cavity that exposes pads of the redistribution structure. The semiconductor die is positioned in the cavity. The semiconductor die includes a first surface, a second surface, sidewalls adjacent the first surface and the second surface, and attachment structures that are operatively coupled to the exposed pads. The encapsulant encapsulates the semiconductor die in the cavity and covers sidewalls of the redistribution structure.

A semiconductor package includes a first connection structure having first and second surfaces and including a first redistribution layer, a first semiconductor chip disposed on the first surface and having a first connection pad electrically connected to the first redistribution layer, a second semiconductor chip disposed around the first semiconductor chip on the first surface and having a second connection pad electrically connected to the first redistribution layer, an interconnection bridge disposed on the second surface to be spaced apart from the second surface and connected to the first redistribution layer through a connection member to electrically connect the first and second connection pads to each other, and a second connection structure disposed on the second surface to embed the interconnection bridge and including a second redistribution layer electrically connected to the first redistribution layer.

An electronic device includes: a first resin layer having a first resin layer main surface and a first resin layer inner surface; a columnar conductor having a columnar conductor main surface and a columnar conductor inner surface and penetrating the first resin layer in direction z; a wiring layer connecting the first resin layer main surface and the first conductor main surface; an electronic component being electrically connected and joined to the wiring layer; a second resin layer having a second resin layer main surface facing the same direction as the first resin layer main surface and a second resin layer inner surface being in contact with the first resin layer main surface, covering the wiring layer and the electronic component; and an external electrode closer to the side where the first resin layer inner surface faces than the first resin layer and is electrically connected to the columnar conductor.

Certain aspects of the present disclosure generally relate to an integrated circuit package having a land-side capacitor electrically coupled to an embedded capacitor. One example integrated circuit package generally includes a package substrate having a first capacitor embedded therein, a semiconductor die disposed above the package substrate, and a second capacitor disposed below the package substrate and electrically coupled to the first capacitor.

Embodiments may include inductors with embedded magnetic cores and methods of making such inductors. In an embodiment, an integrated circuit package may include an integrated circuit die with a multi-phase voltage regulator electrically coupled to the integrated circuit die. In such embodiments, the multi-phase voltage regulator may include a substrate core and a plurality of inductors. The inductors may include a conductive through-hole disposed through the substrate core and a plugging layer comprising a dielectric material surrounding the conductive through-hole. In an embodiment, a magnetic sheath is formed around the plugging layer. In an embodiment, the magnetic sheath is separated from the plated through hole by the plugging layer. Additionally, a first layer comprising a dielectric material may be disposed over a first surface of the magnetic sheath, and a second layer comprising a dielectric material may be disposed over a second surface of the magnetic sheath.

An embodiment of the invention may include a method, and resulting structure, of forming a semiconductor structure. The method may include forming a component hole from a first surface to a second surface of a base layer. The method may include placing an electrical component in the component hole. The electrical component has a conductive structure on both ends of the electrical component. The electrical component is substantially parallel to the first surface. The method may include forming a laminate layer on the first surface of the base layer, the second surface of the base layer, and between the base layer and the electrical component. The method may include creating a pair of via holes, where the pair of holes align with the conductive structures on both ends of the electrical component. The method may include forming a conductive via in the pair of via holes.

A module includes a substrate, a plurality of components on an upper surface of the substrate, a component on a lower surface of the substrate, solder balls on the lower surface, sealing resin layers stacked on the upper surface and the lower surface of the substrate, and a shield film covering a side surface and an upper surface of the module. Part of each solder ball is exposed from a surface of the sealing resin layer, and the exposed parts are shaped to protrude from the sealing resin layer. The module can be connected to a mother substrate by connecting the protruding parts of the solder balls. There are gaps between the solder balls and the sealing resin layer, and the occurrence of cracks in the solder balls can be suppressed by reducing stress arising from a difference in thermal expansion coefficient between the solder and the resin.