A semiconductor package includes a first semiconductor chip including a first semiconductor substrate, and a first upper pad arranged on an upper surface of the first semiconductor substrate, a first polymer layer arranged on the upper surface of the first semiconductor substrate, a second semiconductor chip mounted on the first semiconductor chip, the second semiconductor chip including a second semiconductor substrate and a second lower pad arranged under a lower surface of the second semiconductor substrate, wherein the first polymer layer has a horizontal width in a direction crossing the first polymer layer in a center region of the second semiconductor chip, as a first length, and has a horizontal width in a direction crossing two corner regions of the first polymer layer in corner regions of the second semiconductor chip, as a second length, wherein the second length is greater than the first length.

Techniques are disclosed for facilitating interconnecting semiconductor devices. In one example, a method of interconnecting a first substrate to a second substrate is provided. The method includes forming a first plurality of contacts on the first substrate. The method further includes forming an insulative layer on the first substrate. The method further includes forming a second plurality of contacts on the second substrate. The method further includes joining the first plurality of contacts to the second plurality of contacts to form interconnects between the first substrate and the second substrate. When the first and second substrates are joined, at least a portion of each of the interconnects is surrounded by the insulative layer. Related systems and devices are also provided.

An electronic device includes a substrate, a plurality of micro semiconductor structure, a plurality of conductive members, and a non-conductive portion. The substrate has a first surface and a second surface opposite to each other. The micro semiconductor structures are distributed on the first surface of the substrate. The conductive members electrically connect the micro semiconductor structures to the substrate. Each conductive member is defined by an electrode of one of the micro semiconductor structures and a corresponding conductive pad on the substrate. The non-conductive portion is arranged on the first surface of the substrate. The non-conductive portion includes one or more non-conductive members, and the one or more non-conductive members are attached to the corresponding one or more conductive members of the one or more micro conductive structures.

A package structure and a formation method of a package structure are provided. The method includes disposing a chip structure over a substrate and forming a first adhesive element directly on the chip structure. The first adhesive element has a first thermal conductivity. The method also includes forming a second adhesive element directly on the chip structure. The second adhesive element has a second thermal conductivity, and the second thermal conductivity is greater than the first thermal conductivity. The method further includes attaching a protective lid to the chip structure through the first adhesive element and the second adhesive element.

A joined body includes a first substrate, a second substrate which faces the first substrate, and a joining film which joins the first substrate to the second substrate, wherein the joining film has a first region and a second region, and in a plan view of the first substrate, the first region has a higher metal nanoparticle density than the second region.

A package structure is provided. The package structure includes a chip-containing structure over a substrate and a first adhesive element directly above the chip-containing structure. The first adhesive element has a first thermal conductivity. The package structure also includes multiple second adhesive elements directly above the chip-containing structure. The second adhesive elements are spaced apart from each other, each of the second adhesive elements has a second thermal conductivity, and the second thermal conductivity is greater than the first thermal conductivity. The package structure further includes a protective lid attached to the chip-containing structure through the first adhesive element and the second adhesive elements. The protective lid extends across opposite sidewalls of the chip-containing structure.

MicroLED devices can be transferred in large numbers to form microLED displays using processes such as pick-and-place, thermal adhesion transfer, or fluidic transfer. A blanket solder layer can be applied to connect the bond pads of the microLED devices to the terminal pads of a support substrate. After heating, the solder layer can connect the bond pads with the terminal pads in vicinity of each other. The heated solder layer can correct misalignments of the microLED devices due to the transfer process.

A method of manufacturing an electronic device, comprising fixing a first wafer on a second wafer to form a space theirbetween, via a surrounding member configured to surround the space, forming an opening on a bottom side of the first wafer to expose a conductive member included in the first wafer, and then forming an electrode connected to the conductive member, wherein, in the fixing, the first wafer includes a trench intersecting the surrounding member, on an upper side of the first surface, and, in the forming, the electrode is formed under a condition that the space communicates with an external space via the trench.

The present application is applicable to the field of semiconductor technology and provides a method for packaging stacking a flip chip, which includes: placing a filling template on a substrate, the filling template being provided with a through hole of a preset pattern; filling a filling material into the through hole of the filling template, and after the filling material being formed on the substrate, removing the filling template; placing a chip with solder balls on the substrate formed with the filling material, such that at least a portion of the solder balls being covered by the filling material; and connecting the chip to the substrate through the solder balls, and curing the filling material with air gaps formed between the at least a portion of the solder balls covered with the filling material.

Reliability of a semiconductor device is improved. A power device includes: a semiconductor chip; a chip mounting part; a solder material electrically coupling a back surface electrode of the semiconductor chip with an upper surface of the chip mounting part; a plurality of inner lead parts and a plurality of outer lead parts electrically coupled with an electrode pad of the semiconductor chip through wires; and a sealing body for sealing the semiconductor chip and the wires. Further, a recess is formed in a peripheral region of the back surface of the semiconductor chip. The recess has a first surface extending to join the back surface and a second surface extending to join the first surface. Also, a metal film is formed over the first surface and the second surface of the recess.