Abstract: Cables, cable connectors, and support structures for cantilever package and/or cable attachment may be fabricated using additive processes, such as a coldspray technique, for integrated circuit assemblies. In one embodiment, cable connectors may be additively fabricated directly on an electronic substrate. In another embodiment, seam lines of cables and/or between cables and cable connectors may be additively fused. In a further embodiment, integrated circuit assembly attachment and/or cable attachment support structures may be additively formed on an integrated circuit assembly.

Abstract: Disclosed herein are structures and assemblies that may be used for thermal management in integrated circuit (IC) packages.

Abstract: An integrated circuit assembly may be formed having a substrate, a first integrated circuit device electrically attached to the substrate, a second integrated circuit device electrically attached to the first integrated circuit device, and a heat dissipation device comprising at least one first thermally conductive structure proximate at least one of the first integrated circuit device, the second integrated circuit device, and the substrate; and a second thermally conductive structure disposed over the first thermally conductive structure(s), the first integrated circuit device, and the second integrated circuit device, wherein the first thermally conductive structure(s) have a lower electrical conductivity than an electrical conductivity of the second thermally conductive structure. The first thermally conductive structure(s) may be formed by an additive process or may be pre-formed and attached to at least one of the first integrated circuit device, the second integrated circuit device, and the substrate.

Abstract: Embodiments of the invention include a microelectronic device that includes a first substrate having radio frequency (RF) components and a second substrate that is coupled to the first substrate. The second substrate includes a first conductive layer of an antenna unit for transmitting and receiving communications at a frequency of approximately 4 GHz or higher. A mold material is disposed on the first and second substrates. The mold material includes a first region that is positioned between the first conductive layer and a second conductive layer of the antenna unit with the mold material being a dielectric material to capacitively couple the first and second conductive layers of the antenna unit.

Abstract: Embodiments of the invention include a packaged device with transmission lines that have an extended thickness, and methods of making such device. According to an embodiment, the packaged device may include a first dielectric layer and a first transmission line formed over the first dielectric layer. Embodiments may then include a second dielectric layer formed over the transmission line and the first dielectric layer. According to an embodiment, a first line via may be formed through the second dielectric layer and electrically coupled to the first transmission line. In some embodiments, the first line via extends substantially along the length of the first transmission line.

Abstract: Disclosed herein are structures and assemblies that may be used for thermal management in integrated circuit (IC) packages.

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: Microelectronic die package structures formed according to some embodiments may include a thermal compression bonding (TCB) assembly including a bond head with a first thermal zone separated from a second thermal zone by a thermal separator, the thermal separator extending through a thickness of the bond head. A bond head nozzle is coupled to a first side of the bond head, where the bond head nozzle includes one or more nozzle channels extending through a thickness of the bond head nozzle.

Abstract: Microelectronic die package structures formed according to some embodiments may include a substrate and a die having a first side and a second side. The first side of the die is coupled to the substrate, and a die backside layer is on the second side of the die. The die backside layer includes a plurality of unfilled grooves in the die backside layer. Each of the unfilled grooves has an opening at a surface of the die backside layer, opposite the second side of the die, and extends at least partially through the die backside layer.

Abstract: Embodiments are directed to a device having an overhang portion. In some embodiments, a main body structure of the device comprises an IC die and an exterior surface of the main body structure comprises the overhang portion. The overhang portion adjoins a sidewall structure of the main body structure of the device, which is substantially perpendicular to a backside of the IC die. In some embodiments, the main body structure further comprises a package mold structure, which comprises the overhang portion.

Abstract: Microelectronic die package structures formed according to some embodiments may include a substrate having one or more solder structures. A first set of solder structures is located in a peripheral region of the substrate and a second set of solder structures is located in a central region of the substrate. A height of individual ones of the second set of solder structures is greater than a height of individual ones of the first set of solder structures. A die having a first side and a second side includes one or more conductive die pads on the first side, where individual ones of the conductive die pads are on individual ones of the first set solder structures and on individual ones of the second set solder structures. A die backside layer is on the second side of the die.

Abstract: A modification structure may be formed within a chassis of an electronic product to improve its thermal dissipation systems, to lessen its weight, and/or to enhance its durability, while maintaining the industrial design/esthetics/ergonomics thereof, wherein the modification structure may comprise a plurality of fused modification material particles. The modification structures may have a higher thermal conductivity than the chassis, may have a lower thermal conductivity than the chassis, may have a lower density than the chassis, and/or may have a higher yield strength than the chassis. In a specific example, the modification structure may extend entirely through the chassis and be sufficiently porous to allow air flow to assist in heat dissipation from the electronic product.

Abstract: Microelectronic die package structures formed according to some embodiments may include a thermal compression bonding (TCB) tool including a pedestal having a convex surface to receive a package substrate, a bond head to compress a die against the package substrate, and a heat source thermally coupled to at least one of the pedestal or the bond head.

Abstract: A porous mesh structure for use in the thermal management of integrated circuit devices may be formed as a solid matrix with a plurality of pores dispersed therein, wherein the solid matrix may be a plurality of fused matrix material particles and the plurality of pores may comprise between about 10% and 90% of a volume of the porous mesh structure. The porous mesh structure may be formed on an integrated circuit device and/or on a heat dissipation assembly component, and may be incorporated into an immersion cooling assembly, wherein the porous mesh structure may act as a nucleation site for a working fluid in the immersion cooling assembly.

Abstract: Microelectronic die package structures formed according to some embodiments may include a substrate comprising one or more conductive interconnect structures on a surface of the substrate. One or more support features are on one or more peripheral regions of the surface of the substrate. A first side of a die is coupled to the one or more conductive interconnect structures and is over the one or more support features. A die backside layer is on the second side of the die.

Abstract: A device package and a method of forming a device package are described. The device package has dies disposed on a substrate, and one or more layers with a high thermal conductivity, referred to as the highly-conductive (HC) intermediate layers, disposed on the dies on the substrate. The device package further includes a lid with legs on an outer periphery of the lid, a top surface, and a bottom surface. The legs of the lid are attached to the substrate with a sealant. The bottom surface of the lid is disposed over the one or more HC intermediate layers and the one or more dies on the substrate. The device package may also include thermal interface materials (TIMs) disposed on the HC intermediate layers. The TIMs may be disposed between the bottom surface of the lid and one or more top surfaces of the HC intermediate layers.

Abstract: Cold-spray nozzles, systems, and techniques are described herein related to manufacturing implementations of efficient film deposition. A deposition system includes multiple feed systems to deliver solid powder materials at controlled feed rates and temperatures, and a nozzle, including convergent and divergent sections and connections to the feed systems, to receive a carrier fluid in the convergent section and to spray the carrier fluid and the solid powder materials out of the divergent section. A nozzle includes multiple ports to receive solid powder materials for admission into a carrier fluid, with one or more ports in the convergent section and one or more ports in the divergent section. A method may include delivering a carrier fluid to a nozzle, heating multiple solid powder materials, delivering these solid powder materials to the nozzle, and spraying the solid powder materials out of a divergent section of the nozzle.

Abstract: An integrated circuit assembly may be fabricated to include an integrated circuit device having a backside surface and a metal matrix composite layer on the backside surface, wherein the metal matrix composite layer has a filler material disposed therein to reduce the coefficient of thermal expansion thereof. The filler material may be a plurality of graphitic carbon filler particles, wherein the plurality of graphitic carbon filler particles has an average aspect ratio of greater than about 10, or the filler material may be a plurality of diamond particles, wherein the filler material is clad with a metal material.

Abstract: An integrated circuit assembly may be fabricated to include an integrated circuit device having a backside surface and a metal matrix composite layer on the backside surface, wherein the metal matrix composite layer has a filler material disposed therein that has a graded content to reduce the coefficient of thermal expansion at the backside surface of the integrated circuit device. The filler material may have at least two filler material particle constituents having different particle diameters, wherein a first filler material particle constituent that has the smaller average diameter is closest to the backside surface of the integrated circuit device and wherein a second filler material constituent that has the larger average diameter is farthest from the backside surface of the integrated circuit device.

Abstract: Embodiments may relate to a microelectronic package comprising: a die and a package substrate coupled to the die with a first interconnect on a first face. The package substrate comprises: a second interconnect and a third interconnect on a second face opposite to the first face; a conductive signal path between the first interconnect and the second interconnect; a conductive ground path between the second interconnect and the third interconnect; and an electrostatic discharge (ESD) protection material coupled to the conductive ground path. The ESD protection material comprises a first electrically-conductive carbon allotrope having a first functional group, a second electrically-conductive carbon allotrope having a second functional group, and an electrically-conductive polymer chemically bonded to the first functional group and the second functional group permitting an electrical signal to pass between the first and second electrically-conductive carbon allotropes.