A package is disclosed. In one example, the package comprises a substrate having at least one first recess on a front side and at least one second recess on a back side, wherein the substrate is separated into a plurality of separate substrate sections by the at least one first recess and the at least one second recess, an electronic component mounted on the front side of the substrate, and a single encapsulant filling at least part of the at least one first recess and at least part of the at least one second recess. The encapsulant fully circumferentially surrounds sidewalls of at least one of the substrate sections.

There is provided semiconductor devices and methods of forming the same, the semiconductor devices including: a first semiconductor element having a first electrode; a second semiconductor element having a second electrode; a Sn-based micro-solder bump formed on the second electrode; and a concave bump pad including the first electrode opposite to the micro-solder bump, where the first electrode is connected to the second electrode via the micro-solder bump and the concave bump pad.

A bonding head for a die bonding apparatus and a die bonding apparatus including the bonding head, the bonding head including a head body; a thermal pressurizer mounted on a lower surface of the head body, the thermal pressurizer being configured to hold and heat at least one die and including a heater having a first heating surface that faces a held surface of the die; and a thermal compensator at an outer region of the die, the thermal compensator extending downwardly from the lower surface of the head body and including at least one thermal compensating block having a second heating surface that emits heat from a heating source therein and that faces a side surface of the die held on the thermal pressurizer.

According to one embodiment, a method of manufacturing a semiconductor device includes forming a metal bump on a first surface side of a semiconductor chip, positioning the semiconductor chip so the metal bump contacts a pad of an interconnection substrate, and applying a first light from a second surface side of the semiconductor chip and melting the metal bump with the first light. After the melting, the melted metal bump is allowed to resolidify by stopping or reducing the application of the first light. The semiconductor chip is then pressed toward the interconnection substrate. A second light is then applied from the second surface side of the semiconductor chip while the semiconductor chip is being pressed toward the interconnection substrate to melt the metal bump. After the melting, the melted metal bump is allowed to resolidify by the stopping or reducing of the application of the second light.

A semiconductor structure includes a semiconductor substrate; a first pad and a second pad on a first top surface of the semiconductor substrate; a circuit board including a second top surface, a recess indented from the second top surface into the circuit board, a polymeric pad disposed on the second top surface and corresponding to the first pad, and an active pad disposed within the recess and corresponding to the second pad; a first bump disposed between and contacting the polymeric pad and the first pad; and a second bump disposed between and contacting the active pad and the second pad, wherein a height of the first bump is substantially shorter than a height of the second bump.

A method of forming a semiconductor package is provided. The method includes forming a metallization stack over a semiconductor die. Polymer particles are mounted over the metallization stack. Each of the polymer particles is coated with a first bonding layer. A heat spreader lid is bonded with the semiconductor die by reflowing the first bonding layer. A composite thermal interface material (TIM) structure is formed between the heat spreader lid and the semiconductor die during the bonding. The composite TIM structure includes the first bonding layer and the polymer particles embedded in the first bonding layer.

Systems and methods for multi-height interconnect structures for a semiconductor device are provided herein. The multi-height interconnect structure generally includes a primary level semiconductor die having a primary conductive pillar and a secondary conductive pillar, where the primary conductive pillar has a greater height than the secondary conductive pillar. The semiconductor device may further include a substrate electrically coupled to the primary level semiconductor die through the primary conductive pillar and a secondary level semiconductor die electrically coupled to the primary level semiconductor die through the secondary conductive pillar. The multi-height pillars may be formed using a single photoresist mask or multiple photoresist masks. In some configurations, the primary and secondary conductive pillars may be arranged on only the front-side of the dies and/or substrate.

A patch structure of an integrated circuit package comprises a core having a first side facing downwards and a second side facing upwards. A first solder resist (SR) layer is formed on the first side of the core, wherein the first SR layer comprises a first layer interconnect (FLI) and has a first set of one or more microbumps thereon to bond to one or more logic die. A second solder resist (SR) layer is formed on the second side of the core, wherein the second SR layer has a second set of one or more microbumps thereon to bond with a substrate. One or more bridge dies includes a respective sets of bumps, wherein the one or more bridge dies is disposed flipped over within the core such that the respective sets of bumps face downward and connect to the first set of one or more microbumps in the FLI.

An underfill film for a semiconductor package and a method for manufacturing a semiconductor package using the underfill film are disclosed. The underfill film is suitable for a semiconductor package, which, by including an adhesive layer having low lowest melt viscosity, can improve the connection reliability of a package by minimizing the formation of voids during semiconductor packaging.

A semiconductor device assembly includes a first remote distribution layer (RDL), the first RDL comprising a lower outermost planar surface of the semiconductor device assembly; a first semiconductor die directly coupled to an upper surface of the first RDL by a first plurality of interconnects; a second RDL, the second RDL comprising an upper outermost planar surface of the semiconductor device assembly opposite the lower outermost planar surface; a second semiconductor die directly coupled to a lower surface of the second RDL by a second plurality of interconnects; an encapsulant material disposed between the first RDL and the second RDL and at least partially encapsulating the first and second semiconductor dies; and a third plurality of interconnects extending fully between and directly coupling the upper surface of the first RDL and the lower surface of the second RDL.