Metal-free frame designs for silicon bridges for semiconductor packages and the resulting silicon bridges and semiconductor packages are described. In an example, a semiconductor structure includes a substrate having an insulating layer disposed thereon, the substrate having a perimeter. A metallization structure is disposed on the insulating layer, the metallization structure including conductive routing disposed in a dielectric material stack. A first metal guard ring is disposed in the dielectric material stack and surrounds the conductive routing. A second metal guard ring is disposed in the dielectric material stack and surrounds the first metal guard ring. A metal-free region of the dielectric material stack surrounds the second metal guard ring. The metal-free region is disposed adjacent to the second metal guard ring and adjacent to the perimeter of the substrate.

A semiconductor device includes a first passivation layer over a circuit and. conductive pad over the first passivation layer, wherein the conductive pad is electrically connected to the circuit. A second passivation layer is disposed over the conductive pad and the first passivation layer, and has a first opening and a second opening. The first opening exposes an upper surface of a layer that extends underneath the conductive pad, and the second opening exposes the conductive pad. A first insulating layer is disposed over the second passivation layer and filling the first and second openings. A through substrate via extends through the insulating layer, second passivation layer, passivation layer, and substrate. A side of the through substrate via and the second passivation layer have a gap that is filled with the first insulating layer. A conductive via extends through the first insulating layer and connecting to the conductive pad.

In certain embodiments, a method for designing a semiconductor device includes generating a 2D design for fabricating chiplets on a substrate. The chiplets are component levels for a multi-chip integrated circuit. The 2D design includes a first layout for alignment features and semiconductor structures to be formed on a first surface of a first chiplet and a second layout for alignment features and semiconductor structures to be formed on a first surface of a second chiplet. The first and second chiplets are adjacent on the substrate. The second layout is a mirror image of the first layout across a reference line shared by the first and second chiplets. The first surfaces of the first and second chiplets are both either top or bottom surfaces. The method further includes generating one or more photomasks according to the design.

A multijunction solar cell including an upper first solar subcell having a first band gap and positioned for receiving an incoming light beam; a second solar subcell disposed below and adjacent to and lattice matched with said upper first solar subcell, and having a second band gap smaller than said first band gap; wherein the upper first solar subcell covers less than the entire upper surface of the second solar subcell, leaving an exposed portion of the second solar subcell that lies in the path of the incoming light beam.

An array substrate includes a base substrate, a display region formed on the base substrate, and a non-display region formed on the base substrate around the display region. The non-display region includes a detection line that is provided on the base substrate, and a surface of the detection line away from the base substrate is provided in an undulating shape. A display device is further disclosed.

A semiconductor package can include a semiconductor die stack including a top die and one or more core dies below the top die. The semiconductor package can further include a metal heat sink plated on a top surface of the top die and have a plurality of side surfaces coplanar with corresponding ones of a plurality of sidewalls of the semiconductor die stack. A molding can surround the stack of semiconductor dies and the metal heat sink, the molding including a top surface coplanar with an exposed upper surface of the metal heat sink. The top surface of the molding and the exposed upper surface of the metal heat sink are both mechanically altered. For example, the metal heat sink and the molding can be simultaneously ground with a grinding disc and can show grinding marks as a result.

A semiconductor package can include a semiconductor die stack including a top die and one or more core dies below the top die. The semiconductor package can further include a metal heat sink plated on a top surface of the top die and have a plurality of side surfaces coplanar with corresponding ones of a plurality of sidewalls of the semiconductor die stack. A molding can surround the stack of semiconductor dies and the metal heat sink, the molding including a top surface coplanar with an exposed upper surface of the metal heat sink. The top surface of the molding and the exposed upper surface of the metal heat sink are both mechanically altered. For example, the metal heat sink and the molding can be simultaneously ground with a grinding disc and can show grinding marks as a result.

A resin molding apparatus including a release film feeder configured to feed a release film is provided. The release film feeder including a feeding roller around which the release film is wound, a gripper configured to grip an end portion of the release film fed from the feeding roller, a support table configured to support the release film fed by a horizontal movement of the gripper in an X direction, the support table configured to horizontally move at least one of in the X direction or in a Y direction perpendicular to the X direction, the X and Y directions defining a surface parallel to a surface of the support table, and a position detecting sensor on the support table and configured to detect position information of the release film may be provided.

A conveyance apparatus for conveying a substrate chuck includes a hand for supporting the substrate chuck, a main body for pivotally supporting the hand about a vertical axis and movable in horizontal and vertical directions, and a guiding portion for guiding pivotal motion of the hand. The hand includes hand distal end portions and a hand proximal end portion supported by the main body. An end surface of the hand proximal end portion facing the main body is formed in an arc shape of a circle centered about a vertical axis of a reference position between the hand distal end portions. The guiding portion includes a guiding surface that has a shape corresponding to the end surface of the hand proximal end portion and can slidably contact the end surface.

A conveyance apparatus for conveying a substrate chuck includes a hand for supporting the substrate chuck, a main body for pivotally supporting the hand about a vertical axis and movable in horizontal and vertical directions, and a guiding portion for guiding pivotal motion of the hand. The hand includes hand distal end portions and a hand proximal end portion supported by the main body. An end surface of the hand proximal end portion facing the main body is formed in an arc shape of a circle centered about a vertical axis of a reference position between the hand distal end portions. The guiding portion includes a guiding surface that has a shape corresponding to the end surface of the hand proximal end portion and can slidably contact the end surface.