Abstract: An integrated circuit (IC) package comprising an IC die, the IC die having a first surface and an opposing second surface. The IC die comprises a semiconductor material. The first surface comprises an active layer. A thermoelectric cooler (TEC) comprising a thermoelectric material is embedded within the IC die between the first surface and the second surface and adjacent to the active layer. The TEC has an annular shape that is substantially parallel to the first and second surfaces of the IC die. The thermoelectric material is confined between an outer sidewall along an outer perimeter of the TEC and an inner sidewall along an inner perimeter of the TEC. The outer and inner sidewalls are substantially orthogonal to the first and second surfaces of the IC die.

Abstract: An Integrated Circuit (IC) device structure is provided. The IC device structure includes a first substrate, first one or more dies coupled to a first side of the first substrate by a first plurality of interconnect structures, second one or more dies coupled to a first section of a second side of the substrate by a second plurality of interconnect structures, and a third plurality of interconnect structures to couple a second section of the second side of the substrate to a second substrate. In an example, at least a part of the second one or more dies are within a cavity in the second substrate.

Abstract: An integrated heat spreader includes channel structures assembled in a frame. Each channel structure is independent of the other, and can be used to dissipate heat from integrated circuitry at a specific location within a package, and without allowing heat from that particular location to propagate to integrated circuitry at other locations within the package. Each channel structure can be implemented with metal having a high thermal conductivity (e.g., copper). The channel structures can be used in conjunction with liquid-based cooling or air-based cooling. The frame can be implemented with low thermal conductivity molding compound or plastic so the heat transfer from one channel structure to another is inhibited. The channel structures can have different configurations (e.g., straight, pillars, and/or pin fins) to provide different rates of flow, mixing, and/or cooling. The flow direction of air or liquid for the channel structures can be the same (parallel) or different (counter).

Abstract: Embodiments include a microelectronic device package structure having a first die on the substrate. One or more additional dice are on the first die, and a thermal electric cooler (TEC) is on the first die adjacent at least one of the one or more additional dice. A dummy die is on the TEC, wherein the dummy die is thermally coupled to the first die.

Abstract: Embodiments herein relate to systems, apparatuses, processing, and techniques related to a first heat-conducting plate to be thermally coupled to a first heat source, a thermoelectric cooler (TEC) thermally coupled to the first plate, a second heat-conducting plate thermally coupled to the TEC and to be thermally coupled to a second heat source where the TEC is to at least partially thermally isolate the first plate from the second plate to reduce heat transfer from the first plate to the second plate.

Abstract: Heat dissipation techniques include using metal features having one or more slanted or otherwise laterally-extending aspects. The metal features include, for example, tilted metal pillars, or metal bodies or fillets having an angled or sloping sidewall, or other metal features that extend both vertically and laterally. Such metal features increase the effective heat transfer area significantly by spreading heat in the in-plane (lateral) direction, in addition to the vertical direction. In some embodiments, slanted trenches are formed in photoresist/mold material deposited over a lower die, using photolithography and a multi-angle lens, or by laser drilling mold material deposited over the lower die. The trenches are then filled with metal. In other embodiments, metal features are printed on the lower die, and then molding material is deposited over the printed features. In any such cases, heat is conducted from a lower die to an upper die and/or an integrated heat spreader.

Abstract: Disclosed herein are thermal assemblies for multi-chip packages (MCPs), as well as related methods and devices. For example, in some embodiments, a thermal assembly for an MCP may include a heat pipe having a ring shape.

Abstract: Thermoelectric coolers having solderless electrical interconnects, and semiconductor packages incorporating such thermoelectric coolers, are described. In an example, a thermoelectric cooler includes a solderless electrode electrically connecting a P-type semiconductor column to an N-type semiconductor column, and the solderless electrode is in direct contact with diffusion barrier layers separating the solderless electrode from the P-type and N-type semiconductor material layers of the semiconductor columns. Methods of manufacturing thermoelectric coolers having solderless electrical interconnects are also described.