In an embodiment, a device includes: a package component including integrated circuit dies, an encapsulant around the integrated circuit dies, a redistribution structure over the encapsulant and the integrated circuit dies, and sockets over the redistribution structure; a mechanical brace physically coupled to the sockets, the mechanical brace having openings, each one of the openings exposing a respective one of the sockets; a thermal module physically and thermally coupled to the encapsulant and the integrated circuit dies; and bolts extending through the thermal module, the mechanical brace, and the package component.

Various aspects of the disclosure are directed to circuitry coupled for controlling current flow, such as in a cascode arrangement. As may be consistent with one or more embodiments, an apparatus includes a first transistor having a gate, source, channel and drain, and a second transistor having a gate, and having a stacked source, channel and drain. A conductive clip plate electrically connects the drain of the second transistor to the source of the first transistor, and another conductor electrically connects the source of the second transistor to the gate of the first transistor. The second transistor operates with the connecting structure to provide power by controlling the first transistor in an off-state and in an on-state.

A solar cell module and a method for manufacturing the same are disclosed. The solar cell module includes a plurality of cell cutting pieces stacked and connected in series, and a connector adapted to connect two adjacent cell cutting pieces in series, the plurality of cell cutting pieces being cut from a solar cell, each cell cutting piece including a front electrode and a back electrode, wherein the connector includes a first surface adapted to connect the front electrode and a second surface adapted to connect the back electrode, the first surface is provided with alternating first connecting areas and first disconnecting areas, the second surface is provided with alternating second connecting areas and second disconnecting areas, and projections of the first disconnecting areas on the first surface overlap with projections of the second connecting areas on the first surface, and wherein the front electrode is adapted to connect the first connecting areas, and the back electrode is adapted to connect the second connecting areas. The solar cell module has improved flexibility, in which grid lines and cells are not easy to be broken.

A semiconductor apparatus includes a first substrate having a first surface, a semiconductor device, a first flexible connecting member electrically connected to the semiconductor device, a first pad connected to the first flexible connecting member, and a second substrate including a bump and an interconnect. The second substrate is a low-temperature sintered ceramic substrate containing alkali metal ions. The first pad is connected to the interconnect via the bump. The first pad has at least a portion overlapping the semiconductor device in a plan view seen in a direction along a normal to the first surface. The semiconductor apparatus can thus be miniaturized.

A solar cell module includes: an at least one solar cell disposed between a first cover and a second cover; a sealing material that fills a gap between the first cover and the second cover to join them together, and seals the solar cell; and a tab line as a conductor electrically connected to the solar cell and enclosed by the sealing material between the first cover and the second cover, the tab line having a plurality of bases, and an expansion and contraction portion that can expand and contract in a longitudinal direction and connects the plurality of bases, the plurality of bases each being provided with a through hole and a connection base electrically connected to the solar cell, at least one of the first cover and the second cover having a boss as a positioning unit that positions the tab line.

A semiconductor device and method is disclosed. The semiconductor device may include a semiconductor substrate including an active area, a metal layer structure over the active area, wherein the metal layer structure is configured to form an electrical contact, the metal layer structure including a solder area, a buffer area, and a barrier area between the solder area and the buffer area, wherein, in the barrier area, the metal layer structure is further away from the active area than in the solder area and in the buffer area, and wherein each of the solder area and the buffer area is in direct contact with the active area or with a wiring layer structure arranged between the active area and the metal layer structure.

Package structures and methods of forming the same are disclosed. The package structure includes a package, a device and a screw. The package includes a plurality of dies, an encapsulant encapsulating the plurality of dies, and a redistribution structure over the plurality of dies and the encapsulant. The device is disposed over the package, wherein the dies and the encapsulant are disposed between the device and the redistribution structure. The screw penetrates through the package and the device.

A die attach system is provided. The die attach system includes: a support structure for supporting a substrate; a die supply source including a plurality of die for attaching to the substrate; and a bond head for bonding a die from the die supply source to the substrate, the bond head including a bond tool having a contact portion for contacting the die during a transfer from the die supply source to the substrate, the bond head including a spring portion engaged with the bond tool such that the spring portion is configured to compress during pressing of the die against the substrate using the contact portion of the bond tool.

A semiconductor device is provided with a semiconductor element having a plurality of electrodes, a plurality of terminals electrically connected to the plurality of electrodes, and a sealing resin covering the semiconductor element. The sealing resin covers the plurality of terminals such that a bottom surface of the semiconductor element in a thickness direction is exposed. A first terminal, which is one of the plurality of terminals, is disposed in a position that overlaps a first electrode, which is one of the plurality of electrodes, when viewed in the thickness direction. The semiconductor device is provided with a conductive connection member that contacts both the first terminal and the first electrode.

A semiconductor device includes a first electrode plate, a second electrode plate disposed to oppose the first electrode plate, and a semiconductor chip disposed between the first electrode plate and the second electrode plate. At least one of the first electrode plate and the second electrode plate has a space where a cooling medium circulates.