Abstract: Proximity coupling interconnect packaging systems and methods. A semiconductor package assembly comprises a substrate, a first semiconductor die disposed adjacent the substrate, and a second semiconductor die stacked over the first semiconductor die. There is at least one proximity coupling interconnect between the first semiconductor die and the second semiconductor die, the proximity coupling interconnect comprising a first conductive pad on the first coupling face on the first semiconductor die and a second conductive pad on a second coupling face of the second semiconductor die, the second conductive pad spaced apart from the first conductive pad by a gap distance and aligned with the first conductive pad. An electrical connector is positioned laterally apart from the proximity coupling interconnect and extends between the second semiconductor die and the substrate, the position of the electrical connector defining the alignment of the first conductive pad and the second conductive pad.

Abstract: Semiconductor device package assemblies and associated methods are disclosed herein. In some embodiments, the semiconductor device package assembly includes (1) a base component having a front side and a back side opposite the first side, the base component having a first metallization structure at the front side, the first metallization structure being exposed in a contacting area at the front side; (2) a semiconductor device package having a first side and a second side, the semiconductor device package having a second metallization structure at the first side; and (3) a metal bump at least partially positioned in the recess and electrically coupled to the second metallization structure and the first metallization structure.

Abstract: Disclosed is a microelectronic device assembly comprising a substrate having conductors exposed on a surface thereof. Two or more microelectronic devices are stacked on the substrate, each microelectronic device comprising an active surface operably coupled to conductive traces extending over a dielectric material to via locations beyond at least one side of the stack, at least one surface mount component operably coupled to conductive traces of at least one dielectric material, and vias extending through the dielectric materials at the via locations and comprising conductive material in contact with at least some of the conductive traces of each of the two or more electronic devices and extending to exposed conductors of the substrate.

Abstract: Semiconductor device packages and associated assemblies are disclosed herein. In some embodiments, the semiconductor device package includes a substrate having a first side and a second side opposite the first side, a first metallization layer positioned at the first side of the substrate, and a second metallization layer in the substrate and electrically coupled to the first metallization layer. The semiconductor device package further includes a metal bump electrically coupled to the first metallization layer and a divot formed at the second side of the substrate and aligned with the metal bump. The divot exposes a portion of the second metallization layer and enables the portion to electrically couple to another semiconductor device package.

Abstract: Disclosed is a microelectronic device assembly comprising a substrate having conductors exposed on a surface thereof. Two or more stacks of microelectronic devices are located on the substrate, and microelectronic devices of the stacks are connected to vertical conductive paths external to the stacks and extending to the substrate and to lateral conductive paths extending between the stacks. Methods of fabrication are also disclosed.

Abstract: A semiconductor device, or semiconductor device package, that includes a substrate having an antenna structure on a surface of the substrate and a wire bond that electrically connects the antenna structure to the substrate to form an antenna or a first antenna configuration. The substrate may include a second antenna structure with the wire bond connected to the second antenna structure forming a second antenna or antenna configuration. The semiconductor device may include a radio communication device electrically connected to the substrate. The antenna or antenna configuration may be tuned to the requirements of the radio communication device. The antenna configuration may be tuned by connected to different antenna structures on the surface of the substrate. The antenna configuration may be tuned by changing a length of the wire bond, changing a diameter of the wire bond, and/or changing the material of the wire bond.

Abstract: Semiconductor device packages and associated assemblies are disclosed herein. In some embodiments, the semiconductor device package includes a substrate having a first side and a second side opposite the first side, a first metallization layer positioned at the first side of the substrate, and a second metallization layer in the substrate and electrically coupled to the first metallization layer. The semiconductor device package further includes a metal bump electrically coupled to the first metallization layer and a divot formed at the second side of the substrate and aligned with the metal bump. The divot exposes a portion of the second metallization layer and enables the portion to electrically couple to another semiconductor device package.

Abstract: Systems and methods of manufacture are disclosed for a semiconductor device assembly having a semiconductor device having a first side and a second side opposite of the first side, a mold compound region adjacent to the semiconductor device, a redistribution layer adjacent to the first side of the semiconductor device, a dielectric layer adjacent to the second side of the semiconductor device, a first via extending through the mold compound region that connects to at least one trace in the dielectric layer, and an antenna structure formed on the dielectric layer and connected to the semiconductor device through the first via.

Abstract: Systems and methods for a semiconductor device having an edge-notched substrate are provided. The device generally includes a substrate having a front side, a backside having substrate contacts, and an inward notch at an edge of the substrate. The device includes a die having an active side attached to the front side of the substrate and positioned such that bond pads of the die are accessible from the backside of the substrate through the inward notch. The device includes wire bonds routed through the inward notch and electrically coupling the bond pads of the die to the substrate contacts. The device may further include a second die having an active side attached to the backside of the first die and positioned laterally offset from the first die such that the second bond pads are accessible by wire bonds around the edge of the first die and through the inward notch.

Abstract: Methods of forming supports for 3D structures on semiconductor structures comprise forming the supports from photodefinable materials by deposition, selective exposure and curing. Semiconductor dice including 3D structures having associated supports, and semiconductor devices are also disclosed.

Abstract: Semiconductor devices with antennas and electromagnetic interference (EMI) shielding, and associated systems and methods, are described herein. In one embodiment, a semiconductor device includes a semiconductor die coupled to a package substrate. An antenna structure is disposed over and/or adjacent the semiconductor die. An electromagnetic interference (EMI) shield is disposed between the semiconductor die and the antenna structure to shield at least the semiconductor die from electromagnetic radiation generated by the antenna structure and/or to shield the antenna structure from interference generated by the semiconductor die. A first dielectric material and/or a thermal interface material can be positioned between the semiconductor die and the EMI shield, and a second dielectric material can be positioned between the EMI shield and the antenna structure.

Abstract: Semiconductor assemblies including thermal layers and associated systems and methods are disclosed herein. In some embodiments, the semiconductor assemblies comprise one or more semiconductor devices over a substrate. The substrate includes a thermal layer configured to transfer thermal energy across the substrate. The thermal energy is transferred from the semiconductor device to the graphene layer using one or more thermal connectors.

Abstract: Semiconductor devices having redistribution structures, and associated systems and methods, are disclosed herein. In some embodiments, a semiconductor assembly comprises a die stack including a plurality of semiconductor dies, and a routing substrate mounted on the die stack. The routing substrate includes an upper surface having a redistribution structure. The semiconductor assembly also includes a plurality of electrical connectors coupling the redistribution structure to at least some of the semiconductor dies. The semiconductor assembly further includes a controller die mounted on the routing substrate. The controller die includes an active surface that faces the upper surface of the routing substrate and is electrically coupled to the redistribution structure, such that the routing substrate and the semiconductor dies are electrically coupled to the controller die via the redistribution structure.

Abstract: Semiconductor device assemblies are provided with a layer of thermal barrier material between a first semiconductor device (e.g., a logic die or other heat-generating device) and a second semiconductor device (e.g., a memory die or other device whose performance may be improved in a lower-temperature environment). The layer of thermal barrier material can reduce the conduction of the heat generated by the first semiconductor device towards the second semiconductor device. The assemblies can also include one or more thermally conductive structures disposed in the substrate under the first semiconductor device and configured to conduct the heat from the first semiconductor device out of the semiconductor device assembly.

Abstract: A semiconductor device, or semiconductor device package, that includes a substrate having an antenna structure on a surface of the substrate and a wire bond that electrically connects the antenna structure to the substrate to form an antenna or a first antenna configuration. The substrate may include a second antenna structure with the wire bond connected to the second antenna structure forming a second antenna or antenna configuration. The semiconductor device may include a radio communication device electrically connected to the substrate. The antenna or antenna configuration may be tuned to the requirements of the radio communication device. The antenna configuration may be tuned by connected to different antenna structures on the surface of the substrate. The antenna configuration may be tuned by changing a length of the wire bond, changing a diameter of the wire bond, and/or changing the material of the wire bond.

Abstract: Semiconductor device package assemblies and associated methods are disclosed herein. The semiconductor device package assembly includes (1) a base component having a front side and a back side, the base component having a first metallization structure at the front side; (2) a semiconductor device package having a first side, a second side with a recess, and a second metallization structure at the first side and a contacting region exposed in the recess at the second side; (3) an interconnect structure at least partially positioned in the recess at the second side of the semiconductor device package; and (4) a thermoset material or structure between the front side of the base component and the second side of the semiconductor device package. The interconnect structure is in the thermoset material and includes discrete conductive particles electrically coupled to one another.

Abstract: A semiconductor device assembly can include a first die package comprising a bottom side; a top side; and lateral sides extending between the top and bottom sides. The assembly can include an encapsulant material encapsulating the first die package. In some embodiments, the assembly includes a cooling cavity in the encapsulant material. The cooling cavity can have a first opening; a second opening; and an elongate channel extending from the first opening to the second opening. In some embodiments, the elongate channel surrounds at least two of the lateral sides of the first die package. In some embodiments, the elongate channel is configured to accommodate a cooling fluid.

Abstract: A semiconductor device assembly has a first substrate, a second substrate, and an anisotropic conductive film. The first substrate includes a first plurality of connectors. The second substrate includes a second plurality of connectors. The anisotropic conductive film is positioned between the first plurality of connectors and the second plurality of connectors. The anisotropic conductive film has an electrically insulative material and a plurality of interconnects laterally separated by the electrically insulative material. The plurality of interconnects forms electrically conductive channels extending from the first plurality of connectors to the second plurality of connectors. A method includes connecting the plurality of interconnects to the first plurality of connectors and the second plurality of connectors, such that the electrically conductive channels are operable to conduct electricity from the first substrate to the second substrate.

Abstract: Package-on-package systems for packaging semiconductor devices. In one embodiment, a package-on-package system comprises a first semiconductor package device and a second semiconductor package device. The first package device includes a base substrate including a first side having a die-attach region and a peripheral region, a first semiconductor die attached to the base substrate at the die-attach region, wherein the first semiconductor die has a front side facing the first side of the base substrate and a backside spaced apart from the first side of the base substrate by a first distance, and a high density interconnect array in the perimeter region of the base substrate outside of the die-attach region. The interconnect array has a plurality of interconnects that extend from the first side of the base substrate by a second distance greater than the first distance. The second semiconductor device package is electrically coupled corresponding individual interconnects.

Abstract: Methods for manufacturing semiconductor devices having a flexible reinforcement structure, and associated systems and devices, are disclosed herein. In one embodiment, a method of manufacturing a semiconductor device includes electrically coupling at least one semiconductor die to a redistribution structure on a first carrier. The semiconductor die can include a first surface connected to the redistribution structure and a second surface spaced apart from the redistribution structure. The method also includes reducing a thickness of the semiconductor die to no more than 10 ?m. The method further includes coupling a flexible reinforcement structure to the second surface of the at least one semiconductor die.