The present disclosure provides a semiconductor device package. The semiconductor device package includes a first die, a second die, and a thermal dissipation element. The first die has a first surface. The second die is disposed on the first surface. The thermal dissipation element is disposed on the first surface. The thermal dissipation element includes a first portion extending in a first direction substantially parallel to the first surface and partially covered by the second die and a second portion extending in a second direction substantially perpendicular to the first surface to be adjacent to an edge of the second die.

Semiconductor device assemblies with solderless interconnects, and associated systems and methods are disclosed. In one embodiment, a semiconductor device assembly includes a first conductive pillar extending from a semiconductor die and a second conductive pillar extending from a substrate. The first conductive pillar may be connected to the second conductive pillar via an intermediary conductive structure formed between the first and second conductive pillars using an electroless plating solution injected therebetween. The first and second conductive pillars and the intermediary conductive structure may include copper as a common primary component, exclusive of an intermetallic compound (IMC) of a soldering process. A first sidewall surface of the first conductive pillar may be misaligned with respect to a corresponding second sidewall surface of the second conductive pillar. Such interconnects formed without IMC may improve electrical and metallurgical characteristics of the interconnects for the semiconductor device assemblies.

An electronic device structure and a method for making an electronic device. As non-limiting examples, various aspects of this disclosure provide a method of manufacturing an electronic device that comprises the utilization of a carrier assisted substrate, and an electronic device manufactured thereby.

An electronic device with stud bumps is disclosed. In an embodiment an electronic device includes a carrier board having an upper surface and an electronic chip mounted on the upper surface, the electronic chip having a mounting side facing the upper surface of the carrier board, a top side facing away from the upper surface, and sidewalls connecting the mounting side to the top side, wherein the electronic chip has equal to or less than 5 stud bumps per square millimeter of a base area of the mounting side, wherein the carrier board has at least one recess in the upper surface, and wherein at least one of the stud bumps reaches into the recess.

An electronic device with stud bumps is disclosed. In an embodiment an electronic device includes a carrier board having an upper surface and an electronic chip mounted on the upper surface, the electronic chip having a mounting side facing the upper surface of the carrier board, a top side facing away from the upper surface, and sidewalls connecting the mounting side to the top side, wherein the electronic chip has equal to or less than 5 stud bumps per square millimeter of a base area of the mounting side, wherein the carrier board has at least one recess in the upper surface, and wherein at least one of the stud bumps reaches into the recess.

Microelectronic assemblies, related devices and methods, are disclosed herein. In some embodiments, a microelectronic assembly may include a package substrate having a first surface and an opposing second surface; a first die having a first surface and an opposing second surface embedded in a first dielectric layer, where the first surface of the first die is coupled to the second surface of the package substrate by first interconnects; a second die having a first surface and an opposing second surface embedded in a second dielectric layer, where the first surface of the second die is coupled to the second surface of the first die by second interconnects; and a third die having a first surface and an opposing second surface embedded in a third dielectric layer, where the first surface of the third die is coupled to the second surface of the second die by third interconnects.

Techniques are disclosed for forming a frame on the backplane comprising structures at least partially circumscribing or enclosing metal contacts on the backplane. In some embodiments, the frame may comprise a photoresist. The dimensions and structural integrity of the frame can help prevent misalignment and/or damage of physical obtrusions of light-emitting structures during a bonding process of the light-emitting structures to the backplane.

The present disclosure relates to a fabrication process of a semiconductor chip, which starts with providing a precursor wafer mounted on a carrier. The precursor wafer includes a precursor substrate and component portions between the carrier and the precursor substrate. The precursor substrate is then thinned down to provide a thinned substrate, which includes a substrate base adjacent to the component portions and an etchable region over the substrate base. Next, the etchable region is selectively etched to generate a number of protrusions over the substrate base. Herein, the substrate base is retained, and portions of the substrate base are exposed through the protrusions. Each protrusion protrudes from the substrate base and has a same height. A metal layer is then applied to provide a semiconductor wafer. The metal layer selectively covers the exposed portions of the substrate base and covers at least a portion of each protrusion.

The present disclosure relates to a fabrication process of a semiconductor chip, which starts with providing a precursor wafer mounted on a carrier. The precursor wafer includes a precursor substrate and component portions between the carrier and the precursor substrate. The precursor substrate is then thinned down to provide a thinned substrate, which includes a substrate base adjacent to the component portions and an etchable region over the substrate base. Next, the etchable region is selectively etched to generate a number of protrusions over the substrate base. Herein, the substrate base is retained, and portions of the substrate base are exposed through the protrusions. Each protrusion protrudes from the substrate base and has a same height. A metal layer is then applied to provide a semiconductor wafer. The metal layer selectively covers the exposed portions of the substrate base and covers at least a portion of each protrusion.

The present disclosure relates to a semiconductor chip that includes a substrate, a metal layer, and a number of component portions. Herein, the substrate has a substrate base and a number of protrusions protruding from a bottom surface of the substrate base. The substrate base and the protrusions are formed of a same material. Each of the protrusions has a same height. At least one via hole extends vertically through one protrusion and the substrate base. The metal layer selectively covers exposed surfaces at a backside of the substrate and fully covers inner surfaces of the at least one via hole. The component portions reside over a top surface of the substrate base, such that a certain one of the component portions is electrically coupled to a portion of the metal layer at the top of the at least one via hole.