Abstract: Composite IC chip including a chiplet embedded within metallization levels of a host IC chip. The chiplet may include a device layer and one or more metallization layers interconnecting passive and/or active devices into chiplet circuitry. The host IC may include a device layer and one or more metallization layers interconnecting passive and/or active devices into host chip circuitry. Features of one of the chiplet metallization layers may be directly bonded to features of one of the host IC metallization layers, interconnecting the two circuitries into a composite circuitry. A dielectric material may be applied over the chiplet. The dielectric and chiplet may be thinned with a planarization process, and additional metallization layers fabricated over the chiplet and host chip, for example to form first level interconnect interfaces. The composite IC chip structure may be assembled into a package substantially as a monolithic IC chip.

Abstract: An embedded silicon bridge system including tall interconnect via pillars is part of a system in package device. The tall via pillars may span a Z-height distance to a subsequent bond pad from a bond pad that is part of an organic substrate that houses the embedded silicon bridge.

Abstract: An integrated circuit device may be formed including an electronic substrate and a metallization structure on the electronic substrate, wherein the metallization structure includes a first level comprising a first dielectric material layer, a second level on the first level, wherein the second level comprises a second dielectric material layer, a third level on the second level, wherein the third level comprises a third dielectric material layer, at least one power/ground structure in the second level, and at least one skip level via extending at least partially through the first dielectric material layer of the first level, through the second dielectric layer of the second level, and at least partially through the third dielectric material layer of the third level, wherein the at least one skip level via comprises a continuous conductive material.

Abstract: A heat spreading material is integrated into a composite die structure including a first IC die having a first dielectric material and a first electrical interconnect structure, and a second IC die having a second dielectric material and a second electrical interconnect structure. The composite die structure may include a composite electrical interconnect structure comprising the first interconnect structure in direct contact with the second interconnect structure at a bond interface. The heat spreading material may be within at least a portion of a dielectric area through which the bond interface extends. The heat spreading material may be located within one or more dielectric materials surrounding the composite interconnect structure, and direct a flow of heat generated by one or more of the first and second IC dies.

Abstract: Disclosed herein are structures, devices, and methods for electrostatic discharge protection (ESDP) in integrated circuits (ICs). In some embodiments, an IC package support may include: a first conductive structure; a second conductive structure; and a material in contact with the first conductive structure and the second conductive structure, wherein the material includes a positive temperature coefficient material.

Abstract: Disclosed herein are structures, devices, and methods for electrostatic discharge protection (ESDP) in integrated circuits (ICs). In some embodiments, an IC component may include: a first conductive structure; a second conductive structure; and a material in contact with the first conductive structure and the second conductive structure, wherein the material has a first electrical conductivity before illumination of the material with optical radiation and a second electrical conductivity, different from the first electrical conductivity, after illumination of the material with optical radiation.

Abstract: A heat spreading material is integrated into a composite die structure including a first IC die having a first dielectric material and a first electrical interconnect structure, and a second IC die having a second dielectric material and a second electrical interconnect structure. The composite die structure may include a composite electrical interconnect structure comprising the first interconnect structure in direct contact with the second interconnect structure at a bond interface. The heat spreading material may be within at least a portion of a dielectric area through which the bond interface extends. The heat spreading material may be located within one or more dielectric materials surrounding the composite interconnect structure, and direct a flow of heat generated by one or more of the first and second IC dies.

Abstract: Disclosed herein are structures, devices, and methods for electrostatic discharge protection (ESDP) in integrated circuits (ICs). For example, in some embodiments, an IC package support may include: a first conductive structure in a dielectric material; a second conductive structure in the dielectric material; and a material in contact with the first conductive structure and the second conductive structure, wherein the material includes a polymer, and the material is different from the dielectric material. The material may act as a dielectric material below a trigger voltage, and as a conductive material above the trigger voltage.

Abstract: Disclosed herein are structures, devices, and methods for electrostatic discharge protection (ESDP) in integrated circuits (ICs). In some embodiments, an IC component may include a conductive contact structure that includes a first contact element and a second contact element. The first contact element may be exposed at a face of the IC component, the first contact element may be between the face of the IC component and the second contact element, the second contact element may be spaced apart from the first contact element by a gap, and the second contact element may be in electrical contact with an electrical pathway in the IC component.

Abstract: Various embodiments disclosed relate to a semiconductor package. The present semiconductor package includes a substrate. The substrate is formed from alternating conducting layers and dielectric layers. A first active electronic component is disposed on an external surface of the substrate, and a second active electronic component is at least partially embedded within the substrate. A first interconnect region is formed from a plurality of interconnects between the first active electronic component and the second active electronic component. Between the first active electronic component and the substrate a second interconnect region is formed from a plurality of interconnects. Additionally, a third interconnect region is formed from a plurality of interconnects between the second active electronic component and the substrate.

Abstract: Embodiments may relate to a package substrate that is to couple with the die. The package substrate may include a signal line that is communicatively coupled with the die. The package substrate may further include a conductive line. The package substrate may further include a diode communicatively coupled with the signal line and the conductive line. Other embodiments may be described or claimed.

Abstract: Embodiments may relate to a package substrate that includes a signal line and a ground line. The package substrate may further include a switch communicatively coupled with the ground line. The switch may have an open position where the switch is communicatively decoupled with the signal line, and a closed position where the switch is communicatively coupled with the signal line. Other embodiments may be described or claimed.

Abstract: Disclosed herein are structures, devices, and methods for electrostatic discharge protection (ESDP) in integrated circuits (ICs). For example, in some embodiments, an IC package support may include: a first conductive structure in a dielectric material; a second conductive structure in the dielectric material; and a material in contact with the first conductive structure and the second conductive structure, wherein the material includes a polymer, and the material is different from the dielectric material. The material may act as a dielectric material below a trigger voltage, and as a conductive material above the trigger voltage.

Abstract: Embodiments may relate to a die with a front-end and a backend. The front-end may include a transistor. The backend may include a signal line, a conductive line, and a diode that is communicatively coupled with the signal line and the conductive line. Other embodiments may be described or claimed.

Abstract: Embodiments include a sensor node, an active sensor node, and a vehicle with a communication system that includes sensor nodes. The sensor node include a package substrate, a diplexer/combiner block on the package substrate, a transceiver communicatively coupled to the diplexer/combiner block, and a first mm-wave launcher coupled to the diplexer/combiner block. The sensor node may have a sensor communicatively coupled to the transceiver, the sensor is communicatively coupled to the transceiver by an electrical cable and located on the package substrate. The sensor node may include that the sensor operates at a frequency band for communicating with an electronic control unit (ECU) communicatively coupled to the sensor node. The sensor node may have a filter communicatively coupled to the diplexer/combiner block, the transceiver communicatively coupled to the filter, the filter substantially removes frequencies from RF signals other than the frequency band of the sensor.

Abstract: Waveguides disposed in either an interposer layer or directly in the semiconductor package substrate may be used to transfer signals between semiconductor dies coupled to the semiconductor package. For example, inter-semiconductor die communications using mm-wave carrier signals launched into waveguides specifically tuned to optimize transmission parameters of such signals. The use of such high frequencies beneficially provides for reliable transmission of modulated high data rate signals with lower losses than conductive traces and less cross-talk. The use of mm-wave waveguides provides higher data transfer rates per bump for bump-limited dies as well as beneficially providing improved signal integrity even at such higher data transfer rates. Such mm-wave waveguides may be built directly into semiconductor package layers or may be incorporated into one or more interposed layers that are physically and communicably coupled between the semiconductor dies and the semiconductor package substrate.

Abstract: An Integrated Circuit (IC) device comprising a first component, the first component comprising a first dielectric and a plurality of adjacent first interconnect structures within the first dielectric. The IC device comprising a second component, the second component comprising a second dielectric and a plurality of adjacent second interconnect structures within the second dielectric. A first of the second interconnect structures is in direct contact with a first of the first interconnect structures at a bond interface between the first and second components. A second of the first interconnect structures is set back a distance from a plane of the bond interface.

Abstract: An apparatus comprises a waveguide including: an elongate waveguide core including a dielectric material, wherein the waveguide core includes at least one space arranged lengthwise along the waveguide core that is void of the dielectric material; and a conductive layer arranged around the waveguide core.

Abstract: A method of making a waveguide, comprises: extruding a first dielectric material as a waveguide core of the waveguide, wherein the waveguide core is elongate; and coextruding an outer layer with the waveguide core, wherein the outer layer is arranged around the waveguide core.

Abstract: Techniques and mechanisms for high interconnect density communication with an interposer. In some embodiments, an interposer comprises a substrate and portions disposed thereon, wherein respective inorganic dielectrics of said portions adjoin each other at a material interface, which extends to each of the substrate and a first side of the interposer. A first hardware interface of the interposer spans the material interface at the first side, wherein a first one of said portions comprises first interconnects which couple the first hardware interface to a second hardware interface at the first side. A second one of said portions includes second interconnects which couple one of first hardware interface or the second hardware interface to a third hardware interface at another side of the interposer. In another embodiment, a metallization pitch feature of the first hardware interface is smaller than a corresponding metallization pitch feature of the second hardware interface.