A semiconductor wafer support arrangement and method for processing a semiconductor wafer including an adhesive sheet may comprise: a layer of wafer supporting adhesive that has certain characteristics that permit wafer processing, e.g., wafer thinning, and removal of the processed wafer in condition for use without cleaning. The carrier or substrate for the wafer processing may be reusable, and the adhesive sheet may have plural layers and may include a flexible substrate.

A method for forming a chip package structure is provided. The method includes forming a first redistribution structure over a first carrier substrate. The method includes bonding a chip structure to the first surface through a first conductive bump. The method includes forming a first molding layer over the first redistribution structure. The method includes removing the first carrier substrate. The method includes forming a second conductive bump over the second surface. The method includes forming a second redistribution structure over a second carrier substrate. The method includes bonding the first redistribution structure to the third surface. The method includes forming a second molding layer over the second redistribution structure. The method includes removing the second carrier substrate. The method includes removing a portion of the second redistribution structure from the fourth surface. The method includes forming a third conductive bump over the fourth surface.

A method for forming a chip package structure is provided. The method includes forming a first redistribution structure over a first carrier substrate. The method includes bonding a chip structure to the first surface through a first conductive bump. The method includes forming a first molding layer over the first redistribution structure. The method includes removing the first carrier substrate. The method includes forming a second conductive bump over the second surface. The method includes forming a second redistribution structure over a second carrier substrate. The method includes bonding the first redistribution structure to the third surface. The method includes forming a second molding layer over the second redistribution structure. The method includes removing the second carrier substrate. The method includes removing a portion of the second redistribution structure from the fourth surface. The method includes forming a third conductive bump over the fourth surface.

A semiconductor device includes a first semiconductor element, a first connection terminal formed on a lower surface of the first semiconductor element, a second semiconductor element mounted on the lower surface of the first semiconductor element so that the second semiconductor element partially overlaps the first semiconductor element in plan view, a second connection terminal formed on a lower surface of the second semiconductor element, and a wiring substrate on which the first and second semiconductor elements are mounted. The wiring substrate includes first and second connection pads electrically connected to the first connection terminal and the second connection terminal, respectively. The semiconductor device further includes a third connection terminal formed on the first connection pad and electrically connected to the first connection terminal. One of the first connection terminal and the third connection terminal is a metal post, and the other is a solder ball.

A semiconductor device includes a first semiconductor element, a first connection terminal formed on a lower surface of the first semiconductor element, a second semiconductor element mounted on the lower surface of the first semiconductor element so that the second semiconductor element partially overlaps the first semiconductor element in plan view, a second connection terminal formed on a lower surface of the second semiconductor element, and a wiring substrate on which the first and second semiconductor elements are mounted. The wiring substrate includes first and second connection pads electrically connected to the first connection terminal and the second connection terminal, respectively. The semiconductor device further includes a third connection terminal formed on the first connection pad and electrically connected to the first connection terminal. One of the first connection terminal and the third connection terminal is a metal post, and the other is a solder ball.

The power semiconductor apparatus includes: a semiconductor device 401; a bonding layer on chip 416 disposed on an upper surface of the semiconductor device; and a metal lead 419 disposed on the upper surface of the semiconductor device and bonded to the bonding layer on chip, wherein the metal lead 420 has a three-laminated structure including: a second metal layer 420b having a CTE equal to or less than 5×10.sup.−6/° C., for example; and a first metal layer 420a and a third metal layer 420c sandwiching the second metal layer and having a CTE equal to or greater than the CTE of the second metal layer. Provided is a power semiconductor apparatus capable of improving reliability thereof by reducing a thermal stress to a bonding layer between a semiconductor power device and a metal lead positioned on an upper surface thereof, and reducing a resistance of the metal lead.

The power semiconductor apparatus includes: a semiconductor device 401; a bonding layer on chip 416 disposed on an upper surface of the semiconductor device; and a metal lead 419 disposed on the upper surface of the semiconductor device and bonded to the bonding layer on chip, wherein the metal lead 420 has a three-laminated structure including: a second metal layer 420b having a CTE equal to or less than 5×10.sup.−6/° C., for example; and a first metal layer 420a and a third metal layer 420c sandwiching the second metal layer and having a CTE equal to or greater than the CTE of the second metal layer. Provided is a power semiconductor apparatus capable of improving reliability thereof by reducing a thermal stress to a bonding layer between a semiconductor power device and a metal lead positioned on an upper surface thereof, and reducing a resistance of the metal lead.

A process for the production of a permanent, electrically conductive connection between a first metal surface of a first substrate and a second metal surface of a second substrate, wherein a permanent, electrically conductive connection is produced, at least primarily, by substitution diffusion between metal ions and/or metal atoms of the two metal surfaces.

The power semiconductor apparatus includes: a semiconductor device 401; a bonding layer on chip 416 disposed on an upper surface of the semiconductor device; and a metal lead 419 disposed on the upper surface of the semiconductor device and bonded to the bonding layer on chip, wherein the metal lead 420 has a three-laminated structure including: a second metal layer 420b having a CTE equal to or less than 5×10.sup.−6/° C., for example; and a first metal layer 420a and a third metal layer 420c sandwiching the second metal layer and having a CTE equal to or greater than the CTE of the second metal layer. Provided is a power semiconductor apparatus capable of improving reliability thereof by reducing a thermal stress to a bonding layer between a semiconductor power device and a metal lead positioned on an upper surface thereof, and reducing a resistance of the metal lead.

The power semiconductor apparatus includes: a semiconductor device 401; a bonding layer on chip 416 disposed on an upper surface of the semiconductor device; and a metal lead 419 disposed on the upper surface of the semiconductor device and bonded to the bonding layer on chip, wherein the metal lead 420 has a three-laminated structure including: a second metal layer 420b having a CTE equal to or less than 5×10.sup.−6/° C., for example; and a first metal layer 420a and a third metal layer 420c sandwiching the second metal layer and having a CTE equal to or greater than the CTE of the second metal layer. Provided is a power semiconductor apparatus capable of improving reliability thereof by reducing a thermal stress to a bonding layer between a semiconductor power device and a metal lead positioned on an upper surface thereof, and reducing a resistance of the metal lead.