A semiconductor die package includes a semiconductor die, a film for improving die warpage bonded to a first face of the semiconductor die, a plurality of electrically conductive bumps formed on a second face of the semiconductor die, a substrate onto which the electrically conductive bumps of the second face of the semiconductor die are bonded to electrically connect the semiconductor die and the substrate, and a mold compound applied these components to form an exposed surface of the semiconductor die package that is coplanar with an exposed surface of the film.

A wafer-level chip-scale package includes: a power semiconductor comprising a first semiconductor device formed on a semiconductor substrate, and a second semiconductor device formed on the semiconductor substrate; a common drain electrode connected to the first semiconductor device and the second semiconductor device; a first source metal bump formed on a surface of the first semiconductor device; and a second source metal bump formed on the surface of the second semiconductor device; wherein the first source metal bump, the common drain electrode, and the second source metal bump form a current path in an order of the first source metal bump, the common drain electrode, and the second source metal bump.

A method for manufacturing chip package is disclosed. The method includes providing a wafer having an upper surface and a lower surface opposite thereto, in which the wafer comprises a plurality of conductive pads disposed on the upper surface; dicing the upper surface of the wafer to form a plurality of trenches; forming a patterned photoresist layer on the upper surface and in the trenches; forming a plurality of conductive bumps disposed correspondingly on the conductive pads; thinning the wafer from the lower surface toward the upper surface, such that the patterned photoresist layer in the trenches is exposed from the lower surface; forming an insulating layer under the lower surface; and dicing the patterned photoresist layer and the insulating layer along each trench to form a plurality of chip packages.

A packaged semiconductor device includes a metal substrate having a first and second through-hole aperture having an outer ring, and metal pads around the apertures on dielectric pads. A first and second semiconductor die have a back side metal (BSM) layer on its bottom side are mounted top side up on a top portion of the apertures. A metal die attach layer is directly between the BSM layer and walls of the metal substrate bounding the apertures to provide a die attachment for the first and the second semiconductor die that fills a bottom portion of the apertures. Leads contact the metal pads, wherein the leads include a distal portion that extends beyond the metal substrate. Bondwires are between the metal pads and bond pads on the first and second semiconductor die, and a mold compound provides encapsulation for the packaged semiconductor device.

A method of forming a 3D package. The method may include joining an interposer to a laminate chip carrier with the solid state diffusion of a first plurality of solder bumps by applying a first selective non-uniform heat and first uniform pressure; joining a top chip to the interposer with the solid state diffusion of a second plurality of solder bumps by applying a second selective non-uniform heat and second uniform pressure; heating the 3D package, the first and second pluralities of solder bumps to a temperature greater than the reflow temperature of the first and second pluralities of solder bumps, where the second plurality of solder bumps achieves the reflow temperature before the first plurality of solder bumps, where the first and second selective non-uniform heats being less that the reflow temperature of the first and second pluralities of solder bumps, respectively.

A multi-pin wafer level chip scale package is achieved. One or more solder pillars and one or more solder blocks are formed on a silicon wafer wherein the one or more solder pillars and the one or more solder blocks all have a top surface in a same horizontal plane. A pillar metal layer underlies the one or more solder pillars and electrically contacts the one or more solder pillars with the silicon wafer through an opening in a polymer layer over a passivation layer. A block metal layer underlies the one or more solder blocks and electrically contacts the one or more solder pillars with the silicon wafer through a plurality of via openings through the polymer layer over the passivation layer wherein the block metal layer is thicker than the pillar metal layer.

[Object] To provide a semiconductor protective film capable of suppressing a warpage of a semiconductor chip without impairing productivity and reliability, a semiconductor device including this, and a composite sheet. [Solving Means] A semiconductor protective film 10 according to an embodiment of the present invention includes a protective layer 11 formed of a non-conductive inorganic material and an adhesive layer 12 provided on one surface of the protective layer 11. The protective layer 11 includes at least a vitreous material and is typically formed of plate glass. Accordingly, a warpage of a semiconductor element as a protection target can be suppressed effectively.

A die and a substrate are provided. The die comprises at least one integrated circuit chip, and the substrate comprises first and second subsets of conductive pillars extending at least partially therethrough. Each of the first subset of conductive pillars comprises a protrusion bump pad protruding from a surface of the substrate, and the second subset of conductive pillars each partially form a trace recessed within the surface of the substrate. The die is coupled to the substrate via a plurality of conductive bumps each extending between one of the protrusion bump pads and the die.

A multi-pin wafer level chip scale package is achieved. One or more solder pillars and one or more solder blocks are formed on a silicon wafer wherein the one or more solder pillars and the one or more solder blocks all have a top surface in a same horizontal plane. A pillar metal layer underlies the one or more solder pillars and electrically contacts the one or more solder pillars with the silicon wafer through an opening in a polymer layer over a passivation layer. A block metal layer underlies the one or more solder blocks and electrically contacts the one or more solder pillars with the silicon wafer through a plurality of via openings through the polymer layer over the passivation layer wherein the block metal layer is thicker than the pillar metal layer.

A packaged semiconductor device includes a metal substrate having a first and second through-hole aperture having an outer ring, and metal pads around the apertures on dielectric pads. A first and second semiconductor die have a back side metal (BSM) layer on its bottom side are mounted top side up on a top portion of the apertures. A metal die attach layer is directly between the BSM layer and walls of the metal substrate bounding the apertures to provide a die attachment for the first and the second semiconductor die that fills a bottom portion of the apertures. Leads contact the metal pads, wherein the leads include a distal portion that extends beyond the metal substrate. Bondwires are between the metal pads and bond pads on the first and second semiconductor die, and a mold compound provides encapsulation for the packaged semiconductor device.