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 510.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 510.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 semiconductor device including: a semiconductor element; and a first electrode formed on a first surface of the semiconductor element. The first electrode has a stacked structure including a first electroless Ni plating layer. The first electroless Ni plating layer contains nickel (Ni) and phosphorus (P) as a composition. A phosphorus (P) concentration of the first electroless Ni plating layer is 2.5 wt % to 6 wt % inclusive, and a crystallization rate of Ni.sub.3P in the first electroless Ni plating layer is 0% to 20% inclusive.

A semiconductor device including: a semiconductor element; and a first electrode formed on a first surface of the semiconductor element. The first electrode has a stacked structure including a first electroless Ni plating layer. The first electroless Ni plating layer contains nickel (Ni) and phosphorus (P) as a composition. A phosphorus (P) concentration of the first electroless Ni plating layer is 2.5 wt % to 6 wt % inclusive, and a crystallization rate of Ni.sub.3P in the first electroless Ni plating layer is 0% to 20% inclusive.

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.

The present disclosure provides a conductive particle, its manufacturing method and the anisotropic conductive adhesive. The conductive particle comprises a rigid inner core, a resin layer covering an outer surface of the rigid inner core, and a conductive layer covering an outer surface of the resin layer.

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 510.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 510.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 semiconductor package includes: a semiconductor chip having an active surface, on which a connection pad is disposed, and an inactive surface opposite to the active surface; a heat-dissipating member disposed on the inactive surface of the semiconductor chip and including graphite; an encapsulant sealing at least a portion of each of the semiconductor chip and the heat-dissipating member; a capping metal layer disposed directly between the heat-dissipating member and the encapsulant; and a connection structure disposed on the active surface of the semiconductor chip and including a redistribution layer electrically connected to the connection pad, wherein the heat-dissipating member includes holes passing through at least a portion of the heat-dissipating member, and the holes overlap the inactive surface of the semiconductor chip.