Abstract: An apparatus is provided which comprises: a package substrate, an integrated circuit device coupled to a surface of the package substrate, a first material on the surface of the package substrate, the first material contacting one or more lateral sides of the integrated circuit device, the first material extending at least to a surface of the integrated circuit device opposite the package substrate, two or more separate fins over a surface of the integrated circuit device, the two or more fins comprising a second material having a different composition than the first material, and a third material having a different composition than the second material, the third material over the surface of the integrated circuit device and between the two or more fins. Other embodiments are also disclosed and claimed.

Abstract: An integrated circuit package may be formed having at least one heat dissipation structure within the integrated circuit package itself. In one embodiment, the integrated circuit package may include a substrate; at least one integrated circuit device, wherein the at least one integrated circuit device is electrically attached to the substrate; a mold material on the substrate and adjacent to the at least one integrated circuit device; and at least one heat dissipation structure contacting the at least one integrated circuit, wherein the at least one heat dissipation structure is embedded either within the mold material or between the mold material and the substrate.

Abstract: Ultra-thin, hyper-density semiconductor packages and techniques of forming such packages are described. An exemplary semiconductor package is formed with one or more of: (i) metal pillars having an ultra-fine pitch (e.g., a pitch that is greater than or equal to 150 ?m, etc.); (ii) a large die-to-package ratio (e.g., a ratio that is equal to or greater than 0.85, etc.); and (iii) a thin pitch translation interposer. Another exemplary semiconductor package is formed using coreless substrate technology, die back metallization, and low temperature solder technology for ball grid array (BGA) metallurgy. Other embodiments are described.

Abstract: Ultra-thin, hyper-density semiconductor packages and techniques of forming such packages are described. An exemplary semiconductor package is formed with one or more of: (i) metal pillars having an ultra fine pitch (e.g., a pitch that is greater than or equal to 150 ?m, etc.); (ii) a large die to-package ratio (e.g., a ratio that is equal to or greater than 0.85, etc.); and (iii) a thin pitch translation interposer. Another exemplary semiconductor package is formed using coreless substrate technology, die back metallization, and low temperature solder technology for ball grid array (BGA) metallurgy. Other embodiments are described.

Abstract: An apparatus is provided which comprises: a plurality of dielectric layers forming a substrate, a plurality of first conductive contacts on a first surface of the substrate, a cavity in the first surface of the substrate defining a second surface parallel to the first surface, a plurality of second conductive contacts on the second surface of the substrate, one or more integrated circuit die(s) coupled with the second conductive contacts, and mold material at least partially covering the one or more integrated circuit die(s) and the first conductive contacts. Other embodiments are also disclosed and claimed.

Abstract: An apparatus is provided which comprises: a plurality of dielectric layers forming a substrate, a plurality of first conductive contacts on a first surface of the substrate, a cavity in the first surface of the substrate defining a second surface parallel to the first surface, a plurality of second conductive contacts on the second surface of the substrate, one or more integrated circuit die(s) coupled with the second conductive contacts, and mold material at least partially covering the one or more integrated circuit die(s) and the first conductive contacts. Other embodiments are also disclosed and claimed.

Abstract: Techniques and mechanisms for facilitating heat conductivity in a packaged device with a dummy die. In an embodiment, a packaged device comprises a substrate and one or more IC die coupled thereto. A dummy die structure extends to a bottom of a recess structure formed by a first package mold structure on the substrate. The dummy die structure comprises a polymer resin and a filler, or comprises a metal which has a low coefficient of thermal expansion (CTE). A second package mold structure, which extends to the recess structure, is adjacent to the first package mold structure and to an IC die. In another embodiment, a first CTE of the dummy die is less than a second CTE of one of the package mold structures, and a first thermal conductivity of the dummy die is greater than a second thermal conductivity of the one of the package mold structures.

Abstract: Techniques and mechanisms for facilitating heat conductivity in a packaged device with a dummy die. In an embodiment, a packaged device comprises a substrate and one or more IC die coupled to a surface thereof. A dummy die, adjacent to an IC die and coupled to a region of the substrate, comprises a polymer resin and a filler. A package mold structure of the packaged device adjoins respective sides of the IC die and the dummy die, and adjoins the surface of the substrate. In another embodiment, a first CTE of the dummy die is less than a second CTE of the package mold structure, and a first thermal conductivity of the dummy die is greater than a second thermal conductivity of the package mold structure.

Abstract: An integrated circuit (IC) package comprising a die having a front side and a back side. A solder thermal interface material (STIM) comprising a first metal is over the backside. The TIM has a thermal conductivity of not less than 40 W/mK; and a die backside material (DBM) comprising a second metal over the STIM, wherein the DBM has a CTE of not less than 18×10?6 m/mK, wherein an interface between the STIM and the DBM comprises at least one intermetallic compound (IMC) of the first metal and the second metal.

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: Embodiments disclosed herein include multi-die packages with open cavity bridges. In an example, an electronic apparatus includes a package substrate having alternating metallization layers and dielectric layers. The package substrate includes a first plurality of substrate pads and a second plurality of substrate pads, and an open cavity. A bridge die is in the open cavity, the bridge die including a first plurality of bridge pads, a second plurality of bridge pads, a power delivery bridge pad between the first plurality of bridge pads and the second plurality of bridge pads, and conductive traces. A first die is coupled to the first plurality of substrate pads and the first plurality of bridge pads. A second die is coupled to the second plurality of substrate pads and the second plurality of bridge pads. A power delivery conductive line is coupled to the power delivery bridge pad.

Abstract: Embodiments disclosed herein include multi-die packages with open cavity bridges. In an example, an electronic apparatus includes a package substrate having alternating metallization layers and dielectric layers. The package substrate includes a first plurality of substrate pads and a second plurality of substrate pads. The package substrate also includes an open cavity between the first plurality of substrate pads and the second plurality of substrate pads, the open cavity having a bottom and sides. The electronic apparatus also includes a bridge die in the open cavity, the bridge die including a first plurality of bridge pads, a second plurality of bridge pads, and conductive traces. An adhesive layer couples the bridge die to the bottom of the open cavity. A gap is laterally between the bridge die and the sides of the open cavity, the gap surrounding the bridge die.

Abstract: Embodiments herein relate to systems, apparatuses, or processes directed to a substrate that includes a first region to be coupled with a die, and a second region separate and distinct from the first region that has a lower thermal conductivity than the first region, where the second region is to thermally insulate the first region when the die is coupled to the first region. The thermal insulation of the second region may be used during a TCB process to increase the quality of each of the interconnects of the die by promoting a higher temperature at the connection points to facilitate full melting of solder.

Abstract: Embodiments herein describe techniques for an IC package including a supporting layer having a first zone and a second zone. An electronic component is placed above the first zone of the supporting layer. An underfill material is formed above the first zone of the supporting layer, around or below the electronic component to support the electronic component. The second zone of the supporting layer includes a base area and multiple micro-pillars above the base area, where any two micro-pillars of the multiple micro-pillars are separated by a gap in between. The second zone has a hydrophobic surface including surfaces of the multiple micro-pillars and surfaces of the base area. The second zone is a keep out zone to prevent the underfill material from entering the second zone. Other embodiments may be described and/or claimed.

Abstract: Semiconductor packages with electromagnetic interference (EMI) shielding structures and a method of manufacture therefor is disclosed. In some aspects, a shielding structure can serve as an enclosure formed by conductive material or by a mesh of such material that can be used to block electric fields emanating from one or more electronic components enclosed by the shielding structure at a global package level or local and/or compartment package level for semiconductor packages. In one embodiment, wire and/or ribbon bonding can be used to fabricate the shielding structure. For example, one or more wire and/or ribbon bonds can go from a connecting ground pad on one side of the package to a connecting ground pad on the other side of the package. This can be repeated multiple times at a pre-determined pitch necessary to meet the electrical requirements for shielding, e.g. less than or equal to approximately one half the wavelength of radiation generated by the electronic components being shielded.

Abstract: Embodiments include semiconductor packages and a method to form such semiconductor packages. A semiconductor package includes a plurality of dies on a substrate, and an encapsulation layer over the substrate. The encapsulation layer surrounds the dies. The semiconductor package also includes a plurality of dummy silicon regions on the substrate. The dummy silicon regions surround the dies and encapsulation layer. The plurality of dummy silicon regions are positioned on two or more edges of the substrate. The dummy silicon regions have a top surface substantially coplanar to a top surface of the dies. The dummy silicon regions include materials that include silicon, metals, or highly-thermal conductive materials. The materials have a thermal conductivity of approximately 120 W/mK or greater, or is equal to or greater than the thermal conductivity of silicon. An underfill layer surrounds the substrate and the dies, where the encapsulation layer surrounds portions of the underfill layer.

Abstract: A wide bandwidth signal connector plug, comprising a plurality of signal pins having a first anchor portion and a first mating portion, and a plurality of ground pins having a second anchor portion and a second mating portion. The plurality of ground pins is adjacent to the plurality of signal pins. The plurality of signal pins has a first thickness and the plurality of ground pins has a second thickness that is greater than the first thickness. The first anchor portion has a first width and the second anchor portion has a second width that is greater than the first width.

Abstract: IC packages including a heat spreading material comprising crystalline carbon. The heat spreading material may be applied directly to an IC die surface, for example at a die prep stage, prior to an application or build-up of packaging material, so that the high thermal conductivity may best mitigate any hot spots that develop at the IC die surface during operation. The heat spreading material may be applied to surface of the IC die.

Abstract: IC package including a material preform comprising graphite. The material preform may have a thermal conductivity higher than that of other materials in the package and may therefore mitigate the formation of hot spots within an IC die during device operation. The preform may have high electrical conductivity suitable for EMI shielding. The preform may comprise a graphite sheet that can be adhered to a package assembly with an electrically conductive adhesive, applied, for example over an IC die surface and a surrounding package dielectric material. Electrical interconnects of the package may be coupled to the graphite sheet as an EMI shield. The package preform may be grounded to a reference potential through electrical interconnects of the package, which may be further coupled to a system-level ground plane. System-level thermal solutions may interface with the package-level graphite sheet.

Abstract: Package assemblies with a molded substrate comprising fluid conduits. The fluid conduits may be operable for conveying a fluid (e.g., liquid and/or vapor) through some portion of the package substrate structure. The fluid conveyance may improve thermal management of the package assembly, for example removing heat dissipated by one or more integrated circuits (ICs) of the package assembly.