Abstract: Embodiments herein relate to torque controlled drivers to simultaneously drive fasteners to secure a thermal transfer device to an integrated circuit package. In various embodiments, a torque controlled driver may include a gearbox, a driver with a torque controller and a motor with a rotating shank, a motor gear coupled concentrically with the rotating shank, a bit drive gear in rotational engagement with the motor gear to drive a bit sized to drive a fastener to secure a thermal transfer device to an integrated circuit package, where the gearbox is to hold the motor gear in a position about a motor gear rotational axis and the drive gear about a drive gear rotational axis such that the motor gear and the bit drive gear maintain rotational engagement as the motor gear rotates. Other embodiments may be described and/or claimed.

Abstract: Embodiments are generally directed to a conductive base embedded interconnect. An embodiment of an apparatus includes a substrate; an embedded interconnect layer in a first side of the substrate, the embedded interconnect layer including a plurality of contacts; and one or more conductive paths through the substrate, the one or more conductive paths being connected with the embedded interconnect layers.

Abstract: Embodiments of the invention include a mmWave transceiver and methods of forming such devices. In an embodiment, the mmWave transceiver includes an RF module. The RF module may include a package substrate, a plurality of antennas formed on the package substrate, and a die attached to a surface of the package substrate. In an embodiment, the mmWave transceiver may also include a mainboard mounted to the RF module with one or more solder balls. In an embodiment, a thermal feature is embedded within the mainboard, and the thermal feature is separated from the die by a thermal interface material (TIM) layer. According to an embodiment, the thermal features are slugs and/or vias. In an embodiment, the die compresses the TIM layer resulting in a TIM layer with minimal thickness.

Abstract: An electronic device may include a first die that may include a first set of die contacts. The electronic device may include a second die that may include a second set of die contacts. The electronic device may include a bridge interconnect that may include a first set of bridge contacts and may include a second set of bridge contacts. The first set of bridge contacts may be directly coupled to the first set of die contacts (e.g., with an interconnecting material, such as solder). The second set of bridge contacts may be directly coupled to the second set of die contacts (e.g., with solder). The bridge interconnect may help facilitate electrical communication between the first die and the second die.

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 layer of dielectric material; a conductive pad at least partially on a top surface of the layer of dielectric material; and a layer of material on side surfaces of the conductive pad, wherein the layer of material does not extend onto the top surface of the layer of dielectric material. Other embodiments are also disclosed.

Abstract: A microelectronic device is formed to include an embedded die substrate on an interposer; where the embedded die substrate is formed with no more than a single layer of transverse routing traces. In the device, all additional routing may be allocated to the interposer to which the embedded die substrate is attached. The embedded die substrate may be formed with a planarized dielectric formed over an initial metallization layer supporting the embedded die.

Abstract: An integrated circuit (IC) structure includes a first IC package (ICP), including a first resist surface provided with a first plurality of conductive contacts (CCs), a first recess including a second resist surface disposed at a bottom of the recess and having a second plurality of CCs, and a second recess, including a third resist surface disposed at a bottom of the recess and provided with a fourth plurality of CCs. The IC structure further includes an IC component with a first surface and a second surface, the second surface having a third plurality of CCs coupled to the second plurality of CCs of the first ICP. The IC structure further includes a second ICP having a first surface and a second surface, with one or more CCs located at the second surface and coupled to at least one of the first plurality of CCs of the first ICP.

Abstract: Techniques and mechanisms for providing a bridge between integrated circuit (IC) chips. In an embodiment, the bridge device comprises a semiconductor substrate having disposed thereon contacts to couple the bridge device to two IC chips. Circuit structures and photonic structures of a bridge link are integrated with the substrate. The structures include an optical waveguide coupled between an electrical-to-optical signal conversion mechanism and an optical-to-electrical conversion mechanism. The bridge device converts signaling from an electrical domain to an optical domain and back to an electrical domain. In another embodiment, optical signals received via different respective contacts of an IC chip are converted by the bridge device, where the optical signals are multiplexed with each other and variously propagated with the same optical waveguide.

Abstract: In some embodiments a semiconductor die package includes a package substrate, a plurality of dies each attached to the package substrate, a layer of a thermally conducting sintered paste over the top of each die, a layer of flexible polymer thermal interface material over the sintered paste, and a heat spreader over and thermally connected to the polymer thermal interface material.

Abstract: The present disclosure is directed to systems and methods of conductively coupling a plurality of relatively physically small core dies to a relatively physically larger base die using an electrical mesh network that is formed in whole or in part in, on, across, or about all or a portion of the base die. Electrical mesh networks beneficially permit the positioning of the cores in close proximity to support circuitry carried by the base die. The minimal separation between the core circuitry and the support circuitry advantageously improves communication bandwidth while reducing power consumption. Each of the cores may include functionally dedicated circuitry such as processor core circuitry, field programmable logic, memory, or graphics processing circuitry. The use of core dies beneficially and advantageously permits the use of a wide variety of cores, each having a common or similar interface to the electrical mesh network.

Abstract: An embedded multi-die interconnect bridge apparatus and method includes photolithographically formed interconnects coupled to laser-drilled interconnects. Several structures in the embedded multi-die interconnect bridge apparatus exhibit characteristic planarization during fabrication and assembly.

Abstract: A microelectronic package may be fabricated with at least one compliant external bond pad having at least one integrated spring structure for mitigating the effects of warpage of the microelectronic package during attachment to an external substrate. An embodiment for the microelectronic package may include a microelectronic package substrate having a first surface and an opposing second surface, wherein the microelectronic package substrate includes a void defined therein that extends into the microelectronic package substrate from the second surface thereof, and a compliant bond pad suspended over the void, wherein the compliant bond pad includes a land portion and at least one spring portion, and wherein the at least one spring portion extends from the compliant bond pad land portion to an anchor structure on the microelectronic package substrate second surface.

Abstract: Electronic assemblies and methods including the formation of interconnect structures are described. In one embodiment an apparatus includes semiconductor die and a first metal bump on the die, the first metal bump including a surface having a first part and a second part. The apparatus also includes a solder resistant coating covering the first part of the surface and leaving the second part of the surface uncovered. Other embodiments are described and claimed.

Abstract: Embodiments herein may relate to a package that includes a package substrate with a first die on a first side of the package substrate and a second die on a second side of the package substrate. Solder balls may be coupled with the second side of the package substrate and the second die such that the solder balls are approximately coplanar. Other embodiments may be described and/or claimed.

Abstract: A microelectronic package may be fabricated with at least one compliant external bond pad having at least one integrated spring structure for mitigating the effects of warpage of the microelectronic package during attachment to an external substrate. An embodiment for the microelectronic package may include a microelectronic package substrate having a first surface and an opposing second surface, wherein the microelectronic package substrate includes a void defined therein that extends into the microelectronic package substrate from the second surface thereof, and a compliant bond pad suspended over the void, wherein the compliant bond pad includes a land portion and at least one spring portion, and wherein the at least one spring portion extends from the compliant bond pad land portion to an anchor structure on the microelectronic package substrate second surface.

Abstract: The present disclosure is directed to systems and methods for improving heat distribution and heat removal efficiency in PoP semiconductor packages. A PoP semiconductor package includes a first semiconductor package that is physically, communicably, and conductively coupled to a stacked second semiconductor package. A thermally conductive member that includes at least one thermally conductive member may be disposed between the first semiconductor package and the second semiconductor package. The thermally conductive member may include: a single thermally conductive element; multiple thermally conductive elements; or a core that includes at least one thermally conductive element. The thermally conductive elements are thermally conductively coupled to an upper surface of the first semiconductor package and to the lower surface of the second semiconductor package to facilitate the transfer of heat from the first semiconductor package to the second semiconductor package.

Abstract: A hybrid microelectronic substrate may be formed by the incorporation of a high density microelectronic patch substrate within a lower density microelectronic substrate. The hybrid microelectronic substrate may allow for direct flip chip attachment of a microelectronic device having high density interconnections to the high density microelectronic patch substrate portion of the hybrid microelectronic substrate, while allowing for lower density interconnection and electrical routes in areas where high density interconnections are not required.

Abstract: Hybrid microelectronic substrates, and related devices and methods, are disclosed herein. In some embodiments, a hybrid microelectronic substrate may include a low-density microelectronic substrate having a recess at a first surface, and a high-density microelectronic substrate disposed in the recess and coupled to a bottom of the recess via solder.

Abstract: Electronic assemblies and methods including the formation of interconnect structures are described. In one embodiment an apparatus includes semiconductor die and a first metal bump on the die, the first metal bump including a surface having a first part and a second part. The apparatus also includes a solder resistant coating covering the first part of the surface and leaving the second part of the surface uncovered. Other embodiments are described and claimed.

Abstract: Techniques and mechanisms for providing flexible packaged circuit structures. In an embodiment, a flexible circuit device includes first and second conductive contacts and an interconnect that is coupled between such conductive contacts. While the flexible circuit device is in a baseline (“flat”) configuration, a first side of the flexible circuit device extends at least in part in a flat plane, and a portion of the interconnect includes a point that, with respect to a distance from the flat plane, is a maximum or a minimum of the interconnect. A mold compound of a flexible package encapsulates the portion of the interconnect. In another embodiment, a range spanned by the interconnect along a line orthogonal to the flat plane is at least two times an average height of the interconnect.