Abstract: An electromagnetic interference shield is described for semiconductor chip packages. In some embodiments, a package has a semiconductor die. a redistribution layer, a mold compound over the die, a plurality of vias through the mold compound and outside the die to form a shield, and a metal film over the vias. and over the mold compound.

Abstract: Embodiments of a system and methods for localized high density substrate routing are generally described herein. In one or more embodiments an apparatus includes a medium, first and second circuitry elements, an interconnect element, and a dielectric layer. The medium can include low density routing therein. The interconnect element can be embedded in the medium, and can include a plurality of electrically conductive members therein, the electrically conductive member can be electrically coupled to the first circuitry element and the second circuitry element. The interconnect element can include high density routing therein. The dielectric layer can be over the interconnect die, the dielectric layer including the first and second circuitry elements passing therethrough.

Abstract: Embodiments of the present disclosure are directed towards electro-magnetic interference (EMI) shielding techniques and configurations. In one embodiment, an apparatus includes a first substrate, a die having interconnect structures coupled with the first substrate to route input/output (I/O) signals between the die and the first substrate and a second substrate coupled with the first substrate, wherein the die is disposed between the first substrate and the second substrate and at least one of the first substrate and the second substrate include traces configured to provide electro-magnetic interference (EMI) shielding for the die. Other embodiments may be described and/or claimed.

Abstract: This disclosure relates generally to a system and method including a substrate and an electronic component. The substrate includes a circuit board including a hole, a routing layer, and a first interconnect portion positioned, at least in part, within the hole. The electronic component includes a second interconnect portion, coupled to the first interconnect portion, forming an interconnect between the electronic component and the routing layer.

Abstract: Methods of forming a microelectronic packaging structure and associated structures formed thereby are described. Those methods may include attaching a die to a carrier material, wherein the carrier material comprises a top layer and a bottom layer separated by an etch stop layer; forming a dielectric material adjacent the die, forming a coreless substrate by building up layers on the dielectric material, and then removing the top layer carrier material and etch stop layer from the bottom layer carrier material.

Abstract: Embodiment of the present disclosure describe integrated circuit package assemblies that allow for relatively short connections between devices such as a processor and memory. In one embodiment, a package assembly includes a die embedded in a subpackage directly coupled to another die attached to the subpackage. In some embodiments the subpackage may also contain power management devices. In some embodiments the die embedded in the subpackage and/or the power management device may overlap, or be located in, a region defined by the die coupled to the subpackage such that they are located between the die coupled to the subpackage and a substrate underlying the subpackage. Other embodiments may be described and/or claimed.

Abstract: An apparatus including a die including a first side and an opposite second side including a device side with contact points; and a build-up carrier including at least one layer of conductive material disposed on a first side of the die, and a plurality of alternating layers of conductive material and dielectric material disposed on the second side of the die, wherein the at least one layer of conductive material on the first side of the die is coupled to at least one of (1) at least one of the alternating layers of conductive material on the second side of the die and (2) at least one of the contact points of the die. A method including forming a first portion of a build-up carrier adjacent one side of a die, and forming a second portion of the build-up carrier adjacent another side of the die.

Abstract: A microelectronic package of the present description may comprises a first microelectronic device having at least one row of connection structures electrically connected thereto and a second microelectronic device having at least one row of connection structures electrically connected thereto, wherein the connection structures within the at least one first microelectronic device row are aligned with corresponding connection structures within the at least one second microelectronic device row in an x-direction.

Abstract: This disclosure relates generally to devices, systems, and methods for making a flexible microelectronic assembly. In an example, a polymer is molded over a microelectronic component, the polymer mold assuming a substantially rigid state following the molding. A routing layer is formed with respect to the microelectronic component and the polymer mold, the routing layer including traces electrically coupled to the microelectronic component. An input is applied to the polymer mold, the polymer mold transitioning from the substantially rigid state to a substantially flexible state upon application of the input.

Abstract: Embodiments of the present description relate to the field of fabricating microelectronic structures. The microelectronic structures may include a glass routing structure formed separately from a trace routing structure, wherein the glass routing structure is incorporated with the trace routing substrate, either in a laminated or embedded configuration. Also disclosed are embodiments of a microelectronic package including at least one microelectronic device disposed proximate to the glass routing structure of the microelectronic substrate and coupled with the microelectronic substrate by a plurality of interconnects. Further, disclosed are embodiments of a microelectronic structure including at least one microelectronic device embedded within a microelectronic encapsulant having a glass routing structure attached to the microelectronic encapsulant and a trace routing structure formed on the glass routing structure.

Abstract: A reconstituted wafer includes a rigid mass with a flat surface and a base surface disposed parallel planar to the flat surface. A plurality of dice are embedded in the rigid mass. The plurality of dice include terminals that are exposed through coplanar with the flat surface. A process of forming the reconstituted wafer includes removing some of the rigid mass to expose the terminals, while retaining the plurality of dice in the rigid mass. A process of forming an apparatus includes separating one apparatus from the reconstituted wafer.

Abstract: The present disclosure relates to the field of fabricating microelectronic device packages and, more particularly, to microelectronic device packages having bumpless build-up layer (BBUL) designs, wherein at least one secondary device is disposed within the thickness (i.e. the z-direction or z-height) of the microelectronic device of the microelectronic device package.

Abstract: An example includes a die package including a microelectronic die having a lower die surface, an upper die surface parallel to the lower die surface, and a die side, the microelectronic die including an active region and an inactive region. The example optionally includes a heat spreader having a lower heat spreader surface, an upper heat spreader surface parallel to the lower heat spreader surface, and at least one heat spreader side, the heat spreader disposed on the upper surface of the microelectronic die in thermal communication with the inactive region of the die and electrically insulated from the active region. The example optionally includes an encapsulation material encapsulating the die side and the heat spreader side and lower heat spreader surface, the encapsulation material including a lower surface substantially parallel to the die lower surface and an upper surface substantially parallel to the die upper surface.

Abstract: Embodiments of the present description relate to the field of fabricating microelectronic structures. The microelectronic structures may include a glass routing structure formed separately from a trace routing structure, wherein the glass routing structure is incorporated with the trace routing substrate, either in a laminated or embedded configuration. Also disclosed are embodiments of a microelectronic package including at least one microelectronic device disposed proximate to the glass routing structure of the microelectronic substrate and coupled with the microelectronic substrate by a plurality of interconnects. Further, disclosed are embodiments of a microelectronic structure including at least one microelectronic device embedded within a microelectronic encapsulant having a glass routing structure attached to the microelectronic encapsulant and a trace routing structure formed on the glass routing structure.

Abstract: Methods of forming a microelectronic packaging structure and associated structures formed thereby are described. Those methods may include attaching a die to a carrier material, wherein the carrier material comprises a top layer and a bottom layer separated by an etch stop layer; forming a dielectric material adjacent the die, forming a coreless substrate by building up layers on the dielectric material, and then removing the top layer carrier material and etch stop layer from the bottom layer carrier material.

Abstract: A reconstituted wafer includes a rigid mass with a flat surface and a base surface disposed parallel planar to the flat surface. A plurality of dice are embedded in the rigid mass. The plurality of dice include terminals that are exposed through coplanar with the flat surface. A process of forming the reconstituted wafer includes removing some of the rigid mass to expose the terminals, while retaining the plurality of dice in the rigid mass. A process of forming an apparatus includes separating one apparatus from the reconstituted wafer.

Abstract: Embodiments of the present invention describe a semiconductor package having an embedded die. The semiconductor package comprises a coreless substrate that contains the embedded die. The semiconductor package provides die stacking or package stacking capabilities. Furthermore, embodiments of the present invention describe a method of fabricating the semiconductor package that minimizes assembly costs.

Abstract: Embodiments of the present disclosure are directed towards passivation techniques and configurations for a flexible display. In one embodiment, a flexible display includes a flexible substrate, an array of display elements configured to emit or modulate light disposed on the flexible substrate, and a passivation layer including molecules of silicon (Si) bonded with oxygen (O) or nitrogen (N), the passivation layer being disposed on the array of display elements to protect the array of display elements from environmental hazards.

Abstract: The present disclosure relates to the field of fabricating microelectronic device packages and, more particularly, to microelectronic device packages having bumpless build-up layer (BBUL) designs, wherein at least one secondary device is disposed within the thickness (i.e. the z-direction or z-height) of the microelectronic device of the microelectronic device package.

Abstract: Methods of forming molded panel coreless package structures are described. Those methods and structures may include fabrication of embedded die packages using large panel format and use of molding to improve rigidity of the panel, as well as to embed the die in a non-sacrificial mold material. The methods and structures described include methods for manufacturing thin, coreless substrate architectures which possess low warpage.