A component carrier having a stack with at least one electrically insulating layer structure and/or at least one electrically conductive layer structure and an array of exposed highly thermally conductive cooling structures integrally formed with the stack and defining cooling channels in between is disclosed.

A semiconductor assembly includes a carrier including a dielectric substrate and a plurality of contact pads disposed on an upper surface of the carrier, first and second surface mount packages mounted on the carrier, first and second discrete inductors respectively mounted over the first and second surface mount packages, wherein the first and second surface mount packages each comprise lower surface terminals that face and electrically connect with the contact pads from the carrier, wherein the first and second surface mount packages each comprise an upper side that faces away from the carrier, and wherein the first and second discrete inductors are respectively thermally coupled to the upper sides of the first and second surface mount packages.

An array of through-silicon via (TSV) structures is formed through a silicon substrate, and package-side metal pads are formed on backside surfaces of the array of TSV structures. The silicon substrate is disposed over a carrier substrate, and an epoxy molding compound (EMC) interposer frame is formed around the silicon substrate. A die-side redistribution structure is formed over the silicon substrate and the EMC interposer frame, and at least one semiconductor die is attached to the die-side redistribution structure. The carrier substrate is removed from underneath the package-side metal pads. A package-side redistribution structure is formed on the package-side metal pads and on the EMC interposer frame. Overlay tolerance between the package-side redistribution wiring interconnects and the package-side metal pads increases due to increased areas of the package-side metal pads.

An array of through-silicon via (TSV) structures is formed through a silicon substrate, and package-side metal pads are formed on backside surfaces of the array of TSV structures. The silicon substrate is disposed over a carrier substrate, and an epoxy molding compound (EMC) interposer frame is formed around the silicon substrate. A die-side redistribution structure is formed over the silicon substrate and the EMC interposer frame, and at least one semiconductor die is attached to the die-side redistribution structure. The carrier substrate is removed from underneath the package-side metal pads. A package-side redistribution structure is formed on the package-side metal pads and on the EMC interposer frame. Overlay tolerance between the package-side redistribution wiring interconnects and the package-side metal pads increases due to increased areas of the package-side metal pads.

This disclosure describes an electronic component comprising a package with a top side and a bottom side and at least one electronic chip housed within an enclosure inside the package. The package comprises a package base on its top side and a metallic cap on its bottom side. At least one electronic chip is separated from the metallic cap by a gap and the metallic cap is attached to the package base to form an enclosure.

A packaged semiconductor device includes a substrate having a first surface and a second surface opposite the first surface. At least one semiconductor die is mounted at the first surface of the substrate. Electrically-conductive leads are arranged around the substrate, and electrically-conductive formations couple the at least one semiconductor die to selected leads of the electrically-conductive leads. A package molding material is molded onto the at least one semiconductor die, onto the electrically-conductive leads and onto the electrically-conductive formations. The package molding material leaves the second surface of the substrate uncovered by the package molding material. The substrate is formed by a layer of electrically-insulating material.

A chip package includes a high voltage withstanding substrate and a device chip. The high voltage withstanding substrate has a main body, a functional layer, and a grounding layer. The main body has a top surface, a bottom surface opposite the top surface, a through hole through the top surface and the bottom surface, and a sidewall surrounding the through hole. The functional layer is located on the top surface. The grounding layer covers the bottom surface and the sidewall. The device chip is located on the functional layer, and has a grounding pad that faces the main body. The grounding pad is electrically connected to the grounding layer in the through hole.

A semiconductor device comprises a substrate including a set of interconnect pads, a die mounted on the substrate, wherein the die includes circuitry that cannot withstand typical lead-free (Pb-free) solder reflow temperature during reflow process, and a reinforcing interposer including a first set of interconnect pads and a second set of interconnect pads. Low temperature solder material connects one of the set of interconnect pads on the substrate to a corresponding one of the first set of interconnect pads on the reinforcing interposer. A printed circuit board includes a set of interconnect pads. Low temperature solder material connects one of the set of interconnect pads of the printed circuit board to a corresponding one of the second set of interconnect pads of the reinforcing interposer. The low temperature solder material has a reflow temperature below typical Pb-free solder material.

An apparatus is provided which comprises: a plurality of interconnects to couple a silicon interposer to a substrate; and a landing pad configured in a non-circle shape, wherein the plurality of interconnects are adjacent to the landing pad at one end of the plurality of interconnects through a plurality of vias.

A chip package structure using silicon interposer as interconnection bridge lifts multi-dies above the fan-out molding package embedded with premade Si interposer interconnection bridge under the multi-die space. The interconnection bridge connects the multi-dies through fine pitch high I/O interconnection. A first RDL and a second RDL are further disposed on top side and bottom side of the fan-out molding package, further providing connection for the multi-dies to a substrate via the connection routing inside the fan-out molding package.