Abstract: Disclosed herein are microelectronic structures including bridges, as well as related assemblies and methods. In some embodiments, a microelectronic structure may include a substrate and a bridge.

Abstract: Disclosed herein are microelectronic structures including bridges, as well as related assemblies and methods. In some embodiments, a microelectronic structure may include a substrate and a bridge.

Abstract: A glass substrate houses an embedded multi-die interconnect bridge that is part of a semiconductor device package. Through-glass vias communicate to a surface for mounting on a semiconductor package substrate.

Abstract: Microelectronic assemblies, related devices and methods, are disclosed herein. In some embodiments, a microelectronic component may include a substrate having a first face and an opposing second face, wherein the substrate includes a through-substrate via (TSV); a first mold material region at the first face, wherein the first mold material region includes a first through-mold via (TMV) conductively coupled to the TSV; and a second mold material region at the second face, wherein the second mold material region includes a second TMV conductively coupled to the TSV.

Abstract: An integrated circuit (IC) package substrate, comprising a magnetic material embedded within a dielectric material. A first surface of the dielectric material is below the magnetic material, and a second surface of the dielectric material, opposite the first surface, is over the magnetic material. A metallization level comprising a first metal feature is embedded within the magnetic material. A second metal feature is at an interface of the magnetic material and the dielectric material. The second metal feature has a first sidewall in contact with the dielectric material and a second sidewall in contact with the magnetic material.

Abstract: Embodiments herein relate to systems, apparatuses, and/or processes directed to a package or a manufacturing process flow for creating a package that uses multiple seeding techniques to fill vias in the package. Embodiments include a first layer of copper seeding coupled with a portion of the boundary surface and a second layer of copper seeding coupled with the boundary surface or the first layer of copper seeding, where the first layer of copper seeding and the second layer of copper seeding have a combined thickness along the boundary surface that is greater than a threshold value.

Abstract: A device is disclosed. The device includes a substrate, a die on the substrate, a thermal interface material (TIM) on the die, and solder bumps on a periphery of a top surface of the substrate. An integrated heat spreader (IHS) is formed on the solder bumps. The IHS covers the TIM.

Abstract: Embodiments disclosed herein include electronic packages with thermal solutions. In an embodiment, an electronic package comprises a package substrate, a first die electrically coupled to the package substrate, and an integrated heat spreader (IHS) that is thermally coupled to a surface of the first die. In an embodiment, the IHS comprises a main body having an outer perimeter, and one or more legs attached to the outer perimeter of the main body, wherein the one or more legs are supported by the package substrate. In an embodiment, the electronic package further comprises a thermal block between the package substrate and the main body of the IHS, wherein the thermal block is within the outer perimeter of the main body.

Abstract: Embodiments disclosed herein include electronic packages and methods of making electronic packages. In an embodiment, the electronic package comprises a package substrate, an array of first level interconnect (FLI) bumps on the package substrate, wherein each FLI bump comprises a surface finish, a first pad on the package substrate, wherein the first pad comprises the surface finish, and wherein a first FLI bump of the array of FLI bumps is electrically coupled to the first pad, and a second pad on the package substrate, wherein the second pad is electrically coupled to the first pad.

Abstract: Embodiments disclosed herein include electronic packages and methods of forming such packages. In an embodiment an electronic package comprises a package substrate, and a first level interconnect (FLI) bump region on the package substrate. In an embodiment, the FLI bump region comprises a plurality of pads, and a plurality of bumps, where each bump is over a different one of the plurality of pads. In an embodiment, the electronic package further comprises a guard feature adjacent to the FLI bump region. In an embodiment, the guard feature comprises, a guard pad, and a guard bump over the guard pad, wherein the guard feature is electrically isolated from circuitry of the electronic package.

Abstract: Embodiments disclosed herein include electronic packages with underfill flow control features. In an embodiment, an electronic package comprises a package substrate and a plurality of interconnects on the package substrate. In an embodiment, a die is coupled to the package substrate by the plurality of interconnects and a flow control feature is adjacent on the package substrate. In an embodiment, the flow control feature is electrically isolated from circuitry of the electronic package. In an embodiment, the electronic package further comprises an underfill surrounding the plurality of interconnects and in contact with the flow control feature.

Abstract: Embodiments include package substrates and method of forming the package substrates. A package substrate includes a first encapsulation layer over a substrate, and a second encapsulation layer below the substrate. The package substrate also includes a first interconnect and a second interconnect vertically in the first encapsulation layer, the second encapsulation layer, and the substrate. The first interconnect includes a first plated-through-hole (PTH) core, a first via, and a second via, and the second interconnect includes a second PTH core, a third via, and a fourth via. The package substrate further includes a magnetic portion that vertically surrounds the first interconnect. The first PTH core has a top surface directly coupled to the first via, and a bottom surface directly coupled to the second via. The second PTH core has a top surface directly coupled to the third via, and a bottom surface directly coupled to the fourth via.

Abstract: Embodiments herein describe techniques for a semiconductor device including a package substrate having a core layer. An inductor may include a first coaxial line and a second coaxial line vertically through the core layer, and an interconnect within the package substrate coupling the first coaxial line and the second coaxial line. A first magnetic segment may surround the first coaxial line within the core layer, and a second magnetic segment may surround the second coaxial line within the core layer. In addition, a third magnetic segment may surround the interconnect and be coupled to the first magnetic segment and the second magnetic segment. Other embodiments may be described and/or claimed.

Abstract: Embodiments described herein relate to lithographically defined vertical interconnect accesses (litho-vias) for a bridge die first level interconnect (FLI) and techniques of fabricating such litho-vias. In one example, a package substrate comprises a bridge die embedded in the package substrate; a first contact pad outside a perimeter of the bridge die; a second contact pad inside the perimeter of the bridge die and coupled to the bridge die by a first via; a third pad inside the perimeter of the bridge die, adjacent to the second contact pad, and coupled to the bridge die by a second via. The first contact pad has a surface finish disposed thereon. A first protruded interconnect structure is positioned on the first via and a second protruded interconnect structure is positioned on the second via. Each of the first and second vias have sidewalls that are substantially vertical.

Abstract: A glass substrate houses an embedded multi-die interconnect bridge that is part of a semiconductor device package. Through-glass vias communicate to a surface for mounting on a semiconductor package substrate.

Abstract: A pico cell wireless LAN and pre-emptive roaming algorithm is provided to allow mobile devices in the WLAN to hand-off to another different access point quickly and efficiently. Once associated with an access point (AP), the mobile device receives information about neighboring APs that may be available for hand-off during roaming (or insufficient signal strength). Signal strength of the associated AP is continuously monitored and if signal strength from the associated AP falls below a threshold, the mobile device measures signal strength of the neighboring APs in the list, ranks them, and selects an AP for hand-off. AP load and other information may be used to rank the neighboring APs. The mobile device hands-off to (or associates with) one of the neighboring APs, if appropriate. Hand-offs are attempted in order or rank.

Abstract: Techniques and mechanisms for providing precisely fabricated structures of a semiconductor package. In an embodiment, a build-up carrier of the semiconductor package includes a layer of porous dielectric material. Seed copper and plated copper is disposed on the layer of porous dielectric material. Subsequent etching is performed to remove copper adjacent to the layer of porous dielectric material, forming a gap separating a suspended portion of a MEMS structure from the layer of porous dielectric material. In another embodiment, the semiconductor package includes a copper structure disposed between portions of an insulating layer or portions of a layer of silicon nitride material. The layer of silicon nitride material couples the insulating layer to another insulating layer. One or both of the insulating layers are each protected from desmear processing with a respective release layer structure.

Abstract: Techniques and mechanisms for providing precisely fabricated structures of a semiconductor package. In an embodiment, a build-up carrier of the semiconductor package includes a layer of porous dielectric material. Seed copper and plated copper is disposed on the layer of porous dielectric material. Subsequent etching is performed to remove copper adjacent to the layer of porous dielectric material, forming a gap separating a suspended portion of a MEMS structure from the layer of porous dielectric material. In another embodiment, the semiconductor package includes a copper structure disposed between portions of an insulating layer or portions of a layer of silicon nitride material. The layer of silicon nitride material couples the insulating layer to another insulating layer. One or both of the insulating layers are each protected from desmear processing with a respective release layer structure.

Abstract: A pico cell wireless LAN and pre-emptive roaming algorithm is provided to allow mobile devices in the WLAN to hand-off to another different access point quickly and efficiently. Once associated with an access point (AP), the mobile device receives information about neighboring APs that may be available for hand-off during roaming (or insufficient signal strength). Signal strength of the associated AP is continuously monitored and if signal strength from the associated AP falls below a threshold, the mobile device measures signal strength of the neighboring APs in the list, ranks them, and selects an AP for hand-off. AP load and other information may be used to rank the neighboring APs. The mobile device hands-off to (or associates with) one of the neighboring APs, if appropriate. Hand-offs are attempted in order or rank.

Abstract: A pico cell wireless LAN and pre-emptive roaming algorithm is provided to allow mobile devices in the WLAN to hand-off to another different access point quickly and efficiently. Once associated with an access point (AP), the mobile device receives information about neighboring APs that may be available for hand-off during roaming (or insufficient signal strength). Signal strength of the associated AP is continuously monitored and if signal strength from the associated AP falls below a threshold, the mobile device measures signal strength of the neighboring APs in the list, ranks them, and selects an AP for hand-off. AP load and other information may be used to rank the neighboring APs. The mobile device hands-off to (or associates with) one of the neighboring APs, if appropriate. Hand-offs are attempted in order or rank. Cell sizes in the pico cell WLAN are relatively small, on the order of 1000 square feet or less.