The present disclosure provides a method for preparing a semiconductor device. The method includes forming a sacrificial source/drain structure over a first carrier substrate; forming a redistribution structure over the sacrificial source/drain structure;

attaching the redistribution structure to a second carrier substrate; removing the first carrier substrate after the redistribution structure is attached to the second carrier substrate; replacing the sacrificial source/drain structure with a first source/drain structure; forming a backside contact over and electrically connected to the first source/drain structure; and forming an interconnect part over the backside contact.

A package that includes a first integrated device comprising a first plurality of interconnects; a plurality of solder interconnects coupled to the first plurality of interconnects; a second integrated device comprising a second plurality of interconnects, wherein the second integrated device is coupled to the first integrated device through the second plurality of interconnects, the plurality of solder interconnects and the first plurality of interconnects; a polymer layer located between the first integrated device and the second integrated device; and a plurality of spacer balls located between the first integrated device and the second integrated device.

A module arrangement for power semiconductor devices, includes two or more heat spreading layers with a first surface and a second surface being arranged opposite to the first surface. At least two or more power semiconductor devices are arranged on the first surface of the heat spreading layer and electrically connected thereto. An electrical isolation stack comprising an electrically insulating layer and electrically conductive layers is arranged in contact with the second surface of each heat spreading layer. The at least two or more power semiconductor devices, the heat spreading layers and a substantial part of each of the electrical isolation stacks are sealed from their surrounding environment by a molded enclosure. Accordingly, similar or better thermal characteristic of the module can be achieved instead of utilizing high cost electrically insulating layers, and double side cooling configurations can be easily implemented, without the use of a thick baseplate.

A package base substrate includes a base layer; a plurality of lower surface connection pads disposed on a lower surface of the base layer; a plurality of lower surface wiring patterns disposed on a lower surface of the base layer and respectively connected to a set of lower surface connection pads of the plurality of lower surface connection pads; and a lower surface solder resist layer covering a portion of each of the plurality of lower surface connection pads and the plurality of lower surface wiring patterns on a lower surface of the base layer, wherein each of at least some of the lower surface connection pads of the set of lower surface connection pads has a teardrop shape in a plan view, and includes a ball land portion having a planar circular shape, including a terminal contact portion exposed without being covered by the lower surface solder resist layer, and an edge portion surrounding the terminal contact portion and covered by the lower surface solder resist layer; and a connection reinforcement portion between the ball land portion and the lower surface wiring pattern, including an extension line portion having a width that is the same as a line width of the lower surface wiring pattern and extending from the ball land portion to the lower surface wiring pattern, and a corner reinforcement portion filling a corner between the ball land portion and the extension line portion, and wherein an extension length of the extension line portion has a value greater than a radius of the terminal contact portion.

An electronic module includes at least one electronic component including a first principal surface, first and second electrodes on the first principal surface, a wiring board including a second principal surface, third and fourth electrodes on the second principal surface, and a conductive resin portion. The conductive resin portion includes at least one first conductive resin portion joining the first and third electrodes, and at least one second conductive resin portion joining the second and fourth electrodes. The electronic module further includes at least one reinforcing resin portion that is disposed between at least one first and at least one second conductive resin portions and joins the first principal surface of the electronic component with the second principal surface of the wiring board.

A method for manufacturing a semiconductor device includes preparing a first group of wafers having a plurality of first semiconductor dies embedded in a first photosensitive material layer; forming a plurality of first through vias in the first photosensitive material layer; attaching at least two of the first group of wafers using a first adhesive layer to form a first structure; preparing a second group of wafers having a plurality of second semiconductor dies embedded in a second photosensitive material layer; forming a plurality of second through vias in the second photosensitive material layer; attaching at least two of the second group of wafers using a second adhesive layer to form a second structure; and connecting the first structure to the second structure with a plurality of first metal bumps.

A power module for PCB embedding includes: a leadframe; a power semiconductor die with a first load terminal and control terminal at a first side of the die and a second load terminal at the opposite side, the second load terminal soldered to the leadframe; a first metal clip soldered to the first load terminal and forming a first terminal of the power module at a first side of the power module; and a second metal clip soldered to the control terminal and forming a second terminal of the power module at the first side of the power module. The leadframe forms a third terminal of the power module at the first side of the power module, or a third metal clip is soldered to the leadframe and forms the third terminal. The power module terminals are coplanar within +/−30 μm at the first side of the power module.

A display is created using “smart pixels.” A smart pixel is a pixel of a display that integrates the pixel pipeline as part of the pixel, rather than using separate integrated circuits. A smart pixel may be based on an integrated stack that includes light emitting elements, an external data contact for receiving digital data for that pixel, and also the pixel pipeline from the digital data to the light emitting elements.

A semiconductor package includes first semiconductor chips stacked on a package substrate, a lowermost first semiconductor chip of the first semiconductor chips including a recessed region, and a second semiconductor chip inserted in the recessed region, the second semiconductor chip being connected to the package substrate.

A package structure includes a semiconductor device and an adhesive pattern. The adhesive pattern surrounds the semiconductor device, wherein an angle θ is formed between a sidewall of the semiconductor device and a sidewall of the adhesive pattern, 0°<θ<90° wherein the adhesive layer has a first opening misaligned with a corner of the semiconductor device closest to the first opening.