Embodiments of the present disclosure provide power to backend memory of an IC device from the back side of the device. An example IC device with back-side power delivery for backend memory includes a frontend layer with a plurality of frontend components such as frontend transistors, a backend layer (that may include a plurality of layers) with backend memory (e.g., with one or more eDRAM arrays), and a back-side power delivery structure with a plurality of back-side interconnects electrically coupled to the backend memory, where the frontend layer is between the back-side power delivery structure and the backend layer.

A semiconductor device includes a semiconductor substrate, a TiW layer arranged on the semiconductor substrate a Ti layer arranged on the TiW layer, a Ni alloy layer arranged on the Ti layer, and an Ag layer arranged on the Ni alloy layer, wherein the Ag layer and the Ni alloy layer comprise side faces fabricated by at least one wet etching process, and wherein the Ti layer and the TiW layer comprise side faces fabricated by a dry etching process.

The present disclosure relates to a flip-chip based moisture-resistant module, which includes a substrate with a top surface, a flip-chip die, a sheet-mold film, and a barrier layer. The flip-chip die has a die body and a number of interconnects, each of which extends outward from a bottom surface of the die body and is attached to the top surface of the substrate. The sheet-mold film directly encapsulates sides of the die body, extends towards the top surface of the substrate, and directly adheres to the top surface of the substrate, such that an air-cavity with a perimeter defined by the sheet-mold film is formed between the bottom surface of the die body and the top surface of the substrate. The barrier layer is formed directly over the sheet-mold film, fully covers the sides of the die body, and extends horizontally beyond the flip-chip die.

A semiconductor device assembly can include an assembly substrate having a top surface, a top semiconductor device having a bottom surface, and a plurality of intermediary semiconductor devices. Each of intermediary semiconductor device can be bonded to both the assembly substrate top surface and the top device bottom surface. Each intermediary semiconductor device can also include a semiconductor substrate, a memory array, a first bond pad, a second bond pad, and a conductive column. The first bond pad can electrically couple the assembly substrate to the intermediary semiconductor device; the second bond pad can electrically couple the top semiconductor device to the intermediary semiconductor device; and the conductive column can electrically couple the first bond pad to the second bond pad, and can be exclusive of any electrical connection to the memory array.

Methods for die attachment of multichip and single components may involve printing a sintering paste on a substrate or on the back side of a die. Printing may involve stencil printing, screen printing, or a dispensing process. Paste may be printed on the back side of an entire wafer prior to dicing, or on the back side of an individual die. Sintering films may also be fabricated and transferred to a wafer, die or substrate. A post-sintering step may increase throughput.

A die placement system provides a tip body and die placement head to ensure planarity of a die to substrate without the need for calibration prior to each pick and place operation. A self-aligning tip incorporated into a tip body aids in die placement/attachment. This tip provides for global correction of planarity errors that exist between a die and substrate, regardless of whether those errors stem from gantry (i.e. die-side misalignment) or machine deck tool (i.e. substrate-side misalignment) misalignment.

A package substrate based on a molding process may include an encapsulation layer, a support frame located in the encapsulation layer, a base, a device located on an upper surface of the base, a copper boss located on a lower surface of the base, a conductive copper pillar layer penetrating the encapsulation layer in the height direction, and a first circuit layer and a second circuit layer over and under the encapsulation layer. The second circuit layer includes a second conductive circuit and a heat dissipation circuit, the first circuit layer and the second conductive circuit are connected conductively through the conductive copper pillar layer, the heat dissipation circuit is connected to one side of the device through the copper boss and the base, and the first circuit layer is connected to the other side of the device.

A semiconductor device package comprises a semiconductor device, a first encapsulant surrounding the semiconductor device, a second encapsulant covering the semiconductor device and the first encapsulant, and a redistribution layer extending through the second encapsulant and electrically connected to the semiconductor device.

Implementations of an image sensor package may include an image sensor die including at least one bond pad thereon; a bond wire wirebonded to the at least one bond pad; and an optically transmissive lid coupled to the image sensor die with an optically opaque film adhesive over the at least one bond pad. The bond wire may extend through the optically opaque film adhesive to the at least one bond pad.

An electronic device and a manufacturing method thereof are provided. The electronic device includes a substrate, at least one electronic unit, an adhesive layer, an insulating layer, and a conductive structure. The substrate has at least one recess. The electronic unit is disposed in the recess, and the adhesive layer is disposed between the electronic unit and a bottom surface of the recess. The insulating layer is disposed on the electronic unit and the recess. The conductive structure is disposed on the insulating layer, and the conductive structure penetrates through the insulating layer to be electrically connected to the electronic unit.