Abstract: The present description addresses example methods for forming multi-chip microelectronic devices and the resulting devices. The multiple semiconductor die of the multichip package will be attached to a solid plate with a bonding system selected to withstand stresses applied when a mold material is applied to encapsulate the die of the multichip device. The solid plate will remain as a portion of the finished multi-chip device. The solid plate can be a metal plate to function as a heat spreader for the completed multi-chip device.

Abstract: Described are example microelectronic devices including structures, such as build-up layers, formed of a non-homogeneous photoimageable dielectric material. The non-homogeneous photoimageable dielectric material includes two regions forming opposite surfaces of the material. A first region includes a first carbon content, and a second region located above the first region includes a second carbon content which is greater than that of the first region. The second region of the photoimageable dielectric material provides enhanced adhesion with metal that may be deposited above the material, such as a sputtered metal seed layer to facilitate subsequent deposition of an electroless metal over the non-homogeneous photoimageable dielectric material.

Abstract: An embedded magnetic inductor coil is at least partially exposed in a recess that seats an embedded multi-chip interconnect bridge die on the coil. The embedded multi-chip interconnect bridge die provides a communications bridge between a dominant semiconductive device and a first semiconductive device.

Abstract: A magnetoresistive magnetic tunnel junction (MTJ) stack includes a free magnetic region, a fixed magnetic region, and a dielectric layer positioned between the free magnetic region and the fixed magnetic region. In one aspect, the fixed magnetic region consists essentially of an unpinned, fixed synthetic anti-ferromagnetic (SAF) structure which comprises (i) a first layer of one or more ferromagnetic materials, including cobalt, (ii) a multi-layer region including a plurality of layers of ferromagnetic materials, wherein the plurality of layers of ferromagnetic materials include a layer of one or more ferromagnetic materials including cobalt, and (iii) an anti-ferromagnetic coupling layer disposed between the first layer and the multi-layer region. The free magnetic region may include a circular shape, the one or more ferromagnetic materials of the first layer may include cobalt, iron and boron, and the dielectric layer may be disposed on the first layer.

Abstract: An embedded magnetic inductor coil is at least partially exposed in a recess that seats an embedded multi-chip interconnect bridge die on the coil. The embedded multi-chip interconnect bridge die provides a communications bridge between a dominant semiconductive device and a first semiconductive device.

Abstract: Semiconductor packages having nonspherical filler particles are described. In an embodiment, a semiconductor package includes a package substrate having a dielectric layer over an electrical interconnect. The dielectric layer includes nonspherical filler particles in a resin matrix. The nonspherical filler particles have an aspect ratio greater than one.

Abstract: Described are example microelectronic devices including structures, such as build-up layers, formed of a non-homogeneous photoimageable dielectric material. The non-homogeneous photoimageable dielectric material includes two regions forming opposite surfaces of the material. A first region includes a first carbon content, and a second region located above the first region includes a second carbon content which is greater than that of the first region. The second region of the photoimageable dielectric material provides enhanced adhesion with metal that may be deposited above the material, such as a sputtered metal seed layer to facilitate subsequent deposition of an electroless metal over the non-homogeneous photoimageable dielectric material.

Abstract: The present description addresses example methods for forming multi-chip microelectronic devices and the resulting devices. The multiple semiconductor die of the multichip package will be attached to a solid plate with a bonding system selected to withstand stresses applied when a mold material is applied to encapsulate the die of the multichip device. The solid plate will remain as a portion of the finished multi-chip device. The solid plate can be a metal plate to function as a heat spreader for the completed multi-chip device.

Abstract: Various embodiments include, for example, a magnetic-dielectric film-based inductor that can be embedded in an electronic package for use as an integrated voltage-regulator, multiple conductive regions to provide electrical interconnects to the magnetic-dielectric-based inductor from other devices, multiple conductive pillars that are electrically coupled to and formed over at least some of the conductive regions, and a magnetic-dielectric layer formed over at least some of conductive regions and conductive pillars. The magnetic-dielectric layer is formed by a multi-layer formation technique having multiple dielectric-material layers and multiple magnetic-material layers. Each of the magnetic-material layers is interspersed with at least one of the dielectric-material layers. Other devices, apparatuses, and methods are described.

Abstract: Disclosed herein are integrated circuit (IC) package supports having inductors with magnetic material therein. For example, in some embodiments, an IC package support may include an inductor including a solenoid, a first portion of a magnetic material in an interior of the solenoid, and a second portion of magnetic material outside the interior of the solenoid.

Abstract: Disclosed herein are integrated circuit (IC) package substrates formed with a dielectric bi-layer, and related devices and methods. In some embodiments, an IC package substrate is fabricated by: forming a raised feature on a conductive layer; forming a dielectric bi-layer on the conductive layer, where the dielectric bi-layer includes a first sub-layer having a first material property and a second sub-layer having a second material property, and where the top surface of the second sub-layer is substantially planar with the top surface of the raised feature; and removing the first sub-layer until the second material property is detected to reveal the conductive feature. In some embodiments, an IC package substrate is fabricated by: forming a dielectric bi-layer on a patterned conductive layer, where the first sub-layer is less susceptible to removal than the second sub-layer; forming an opening in the dielectric bi-layer; etching; and forming a via having vertical sidewalls.

Abstract: An electroless nickel, electroless palladium, electroless tin stack and. associated methods are shown. An example method to form a solder bump may include forming a layer of a second material over a first material at a base of a trench in a solder resist layer. The first material includes nickel and the second material includes palladium. The method further includes depositing a third material that includes tin on the second material using an electroless deposition process, and forming a solder bump out of the third material using a reflow and deflux process.

Abstract: A package assembly includes a substrate and at least a first die having a first contact array and a second contact array. First and second via assemblies are respectively coupled with the first and second contact arrays. Each of the first and second via assemblies includes a base pad, a cap assembly, and a via therebetween. One or more of the cap assembly or the via includes an electromigration resistant material to isolate each of the base pad and the cap assembly. Each first cap assembly and via of the first via assemblies has a first assembly profile less than a second assembly profile of each second cap assembly and via of the second via assemblies. The first and second cap assemblies have a common applied thickness in an application configuration. The first and second cap assemblies have a thickness variation of ten microns or less in a reflowed configuration.

Abstract: Semiconductor packages having a die electrically connected to an antenna by a coaxial interconnect are described. In an example, a semiconductor package includes a molded layer between a first antenna patch and a second antenna patch of the antenna. The first patch may be electrically connected to the coaxial interconnect, and the second patch may be mounted on the molded layer. The molded layer may be formed from a molding compound, and may have a stiffness to resist warpage during fabrication and use of the semiconductor package.

Abstract: Disclosed herein are integrated circuit (IC) package supports and related apparatuses and methods. For example, in some embodiments, an IC package support may include a non-photoimageable dielectric, and a conductive via through the non-photoimageable dielectric, wherein the conductive via has a diameter that is less than 20 microns. Other embodiments are also disclosed.

Abstract: Integrated circuit package substrates with high-density interconnect architecture for scaling high-density routing, as well as related structures, devices, and methods, are generally presented. More specifically, integrated circuit package substrates with fan out routing based on a high-density interconnect layer that may include pillars and vias, and integrated cavities for die attachment are presented. Additionally, integrated circuit package substrates with self-aligned pillars and vias formed on the high-density interconnect layer as well as related methods are presented.

Abstract: A stretchable electronic assembly comprising a stretchable body, a plurality of electronic components encapsulated in the stretchable body, at least one meandering conductor connected to at least one electronic component of the plurality of electronic components, at least one hollow pocket formed in the stretchable body, the at least one meandering conductor encapsulated in the stretchable body and the at least one meandering conductor located within the at least one hollow pocket formed in the stretchable body.

Abstract: Described are microelectronic devices including an embedded die substrate including a molded component formed on or over a surface of a laminated substrate that provides a planar outer surface independent of the contour of the adjacent laminated substrate surface. The molded component may be formed over at least a portion of the embedded die. In other examples, the molded component and resulting planar outer surface may alternatively be on the backside of the substrate, away from the embedded die. The molded component may include an epoxy mold compound; and may be formed through processes including compression molding and transfer molding.

Abstract: An electroless nickel, electroless palladium, electroless tin stack and associated methods are shown. An example method to form a solder bump may include forming a layer of a second material over a first material at a base of a trench in a solder resist layer. The first material includes nickel and the second material includes palladium. The method further includes depositing a third material that includes tin on the second material using an electroless deposition process, and forming a solder bump out of the third material using a reflow and deflux process.

Abstract: Methods/structures of forming package structures are described. Those methods/structures may include forming a first conductive trace adjacent a second conductive trace on a dielectric material of a high density package substrate. A barrier layer is formed on at least one of the first conductive trace or the second conductive trace, wherein the barrier layer comprises a corrosion resistant material, and forming a conductive via on a portion of the barrier layer.