Abstract: Embodiments include package substrates and method of forming the package substrates. A package substrate includes a first encapsulation layer over a substrate, and a second encapsulation layer below the substrate. The package substrate also includes a first interconnect and a second interconnect vertically in the first encapsulation layer, the second encapsulation layer, and the substrate. The first interconnect includes a first plated-through-hole (PTH) core, a first via, and a second via, and the second interconnect includes a second PTH core, a third via, and a fourth via. The package substrate further includes a magnetic portion that vertically surrounds the first interconnect. The first PTH core has a top surface directly coupled to the first via, and a bottom surface directly coupled to the second via. The second PTH core has a top surface directly coupled to the third via, and a bottom surface directly coupled to the fourth via.

Abstract: A substrate for an electronic device may include a first layer, and the first layer may include dielectric material. The first layer may include a first interconnect, and the first interconnect may have a first interconnect profile. The substrate may include a second layer, and the second layer may include dielectric material. The second layer may include a second interconnect, and the second interconnect may have a second interconnect profile. The first interconnect profile may be indicative of a subtractive manufacturing operation and the second interconnect profile may be indicative of an additive manufacturing operation.

Abstract: A device is disclosed. The device includes a first insulating film structure, a plurality of conductor layers above the first insulating film structure, a Ti structure and a nanocube structure between respective layers of the plurality of conductor layers, the nanocube structure above the Ti structure, and a second insulating film structure above a topmost conductor layer of the plurality of conductor layers.

Abstract: Embodiments include semiconductor packages and method of forming the semiconductor packages. A semiconductor package includes first waveguides over a package substrate. The first waveguides include first angled conductive layers, first transmission lines, and first cavities. The semiconductor package also includes a first dielectric over the first waveguides and package substrate, second waveguides over the first dielectric and first waveguides, and a second dielectric over the second waveguides and first dielectric. The second waveguides include second angled conductive layers, second transmission lines, and second cavities. The first angled conductive layers are positioned over the first transmission lines and package substrate having a first pattern of first triangular structures.

Abstract: A thin-film insulator comprises a first electrode over a substrate. A photo up-converting material is over the first electrode. A cured photo-imageable dielectric (PID) containing a high-k filler material is over the photo up-converting material, wherein the cured PID is less than 4 ?m in thickness, and a second electrode is over the cured PID.

Abstract: A filter structure comprises a first dielectric buildup film. A second dielectric buildup film is over the first dielectric buildup film, the second dielectric buildup film including a metallization catalyst. A trench is in the second dielectric buildup film. A metal is selectively plated to sidewalls of the trench based at least in part on the metallization catalyst. A low-loss buildup film is over the metal that substantially fills the trench.

Abstract: Embodiments disclosed herein include electronic packages with a ground plate embedded in the solder resist that extends over signal traces. In an embodiment, the electronic package comprises a substrate layer, a trace over the substrate layer, and a first pad over the substrate layer. In an embodiment, a solder resist is disposed over the trace and the first pad. In an embodiment a trench is formed into the solder resist, and the trench extends over the trace. In an embodiment, a conductive plate is disposed in the trench, and is electrically coupled to the first pad by a via that extends from a bottom surface of the trench through the solder resist.

Abstract: A package for an electronic device may include a first layer. The first layer may include a first dielectric material. The first layer may have a planar first surface. The first layer may have a variable thickness. A second layer may be coupled to the first layer. The second layer may include a second dielectric material and may have a planar second surface. The second layer may have a variable thickness. A seam may be located at an interface between the first layer and the second layer, and the seam may have an undulating profile. The package may include at least one electrical trace, for example located in the first layer or the second layer.

Abstract: A substrate for an electronic device may include a first layer, a second layer, and may include a third layer. The first layer may include a capacitive material, and the capacitive material may be segmented into a first section, and a second section. Each of the first section and the second section may include a first surface and a second surface. The second layer may include a first conductor. The third layer may include a second conductor. The first surface of the second section of capacitive material may be directly coupled to the first conductor. The second surface of the second section of the capacitive material may be directly coupled to the second conductor. A first filler region may include a dielectric material and the first filler region may be located in a first gap between the first section of capacitive material and the second section of capacitive material.

Abstract: Embodiments disclosed herein include electronic packages and methods of forming such packages. In an embodiment, the electronic package comprises a substrate and a conductive feature over the substrate. In an embodiment, a metallic mask is positioned over the conductive feature. In an embodiment, the metallic mask extends beyond a first edge of the conductive feature and a second edge of the conductive feature.

Abstract: Microelectronic assemblies, and related devices and methods, are disclosed herein. For example, in some embodiments, a microelectronic assembly may include a substrate layer having a surface, wherein the substrate layer includes a photo-imageable dielectric (PID) and an electroless catalyst; a first conductive trace having a first thickness on the surface of the substrate layer; and a second conductive trace having a second thickness on the surface of the substrate layer, wherein the first thickness is greater than the second thickness.

Abstract: Disclosed embodiments include in-recess fabricated vertical capacitor cells, that can be assembled as close to the surface of a semiconductor package substrate as the first-level interconnect surface. The in-recess fabricated vertical capacitor cells are semiconductor package-integrated capacitors. Disclosed embodiments include laminated vertical capacitor cells where a plated through-hole is twice breached to form opposing capacitor plates. The breached, plated through-hole capacitors are semiconductor package-integrated capacitors.

Abstract: Embodiments include package substrates and a method of forming the package substrates. A package substrate includes a dielectric having a cavity that has a footprint, a resistor embedded in the cavity of the dielectric, and a plurality of traces on the resistor, where a plurality of surfaces of the resistor are activated surfaces. The resistor may also have a plurality of sidewalls which may be activated sidewalls and tapered. The dielectric may include metallization particles/ions. The resistor may include resistive materials, such as nickel-phosphorus (NiP), aluminum-nitride (AlN), and/or titanium-nitride (TiN). The package substrate may further include a first resistor embedded adjacently to the resistor. The first resistor may have a first footprint of a first cavity that is different than the footprint of the cavity of the resistor. The resistor may have a resistance value that is thus different than a first resistance value of the first resistor.

Abstract: Disclosed embodiments include in-recess fabricated vertical capacitor cells, that can be assembled as close to the surface of a semiconductor package substrate as the first-level interconnect surface. The in-recess fabricated vertical capacitor cells are semiconductor package-integrated capacitors. Disclosed embodiments include laminated vertical capacitor cells where a plated through-hole is twice breached to form opposing capacitor plates. The breached, plated through-hole capacitors are semiconductor package-integrated capacitors.

Abstract: Disclosed embodiments include in-recess fabricated vertical capacitor cells, that can be assembled as close to the surface of a semiconductor package substrate as the first-level interconnect surface. The in-recess fabricated vertical capacitor cells are semiconductor package-integrated capacitors. Disclosed embodiments include laminated vertical capacitor cells where a plated through-hole is twice breached to form opposing capacitor plates. The breached, plated through-hole capacitors are semiconductor package-integrated capacitors.

Abstract: A system is disclosed, which comprises a component carrier having a first side, and a second side opposite the first side; and a light source to couple light into the carrier. In an example, the carrier is to propagate, through internal reflection, at least a portion the light to both the first and second sides of the carrier. The portion of light may be sufficient to release a first component and second component affixed to the first and second sides of the carrier via a first photosensitive layer and second photosensitive layer, respectively.

Abstract: A magnetic material may be fabricated with a plurality of magnetic filler particles dispersed within a carrier material, wherein at last one of the magnetic filler particles may comprise a ferromagnetic core coated with an inert material to form a shell surrounding the ferromagnetic core. Such a coating may allow for the use of ferromagnetic materials for forming embedded inductors in package substrates without the risk of being incompatible with fabrication processes used to form these package substrates.

Abstract: Embodiments of the present disclosure describe selective metallization of an integrated circuit (IC) substrate. In one embodiment, an integrated circuit (IC) substrate may include a dielectric material and metal crystals having a polyhedral shape dispersed in the dielectric material and bonded with a ligand that is to ablate when exposed to laser light such that the metal crystals having the ablated ligand are activated to provide a catalyst for selective electroless deposition of a metal. Other embodiments may be described and/or claimed.

Abstract: Embodiments of the present disclosure describe selective metallization of an integrated circuit (IC) substrate. In one embodiment, an integrated circuit (IC) substrate may include a dielectric material and metal crystals having a polyhedral shape dispersed in the dielectric material and bonded with a ligand that is to ablate when exposed to laser light such that the metal crystals having the ablated ligand are activated to provide a catalyst for selective electroless deposition of a metal.

Abstract: A build-up layer may be fabricated by forming a microelectronic dielectric layer comprising a dielectric material with a metallization catalyst dispersed therein, forming a primer layer on the microelectronic dielectric layer, and forming a recess through the primer layer and into the dielectric material layer. An activation layer may be formed in or on the exposed microelectronic dielectric layer within the recess, wherein the primer layer acts as a mask. A metal layer may be formed on the activation layer, such as with an electroless process. Thus, the resolution of the metal layer deposition may be precisely controlled by the process used to form the recess.