A semiconductor device manufacturing method including preparing a semiconductor substrate including an electrode; forming a wire connected to the electrode; forming a first insulating film including a first opening that partially exposes the wire; forming a base portion that is connected to a portion of the wire exposed via the first opening, and that includes a conductor including a recess corresponding to the first opening; forming a solder film on a surface of the base portion; and fusing solder included in the solder film by a first heat treatment, and filling the recess with the fused solder.

A packaged semiconductor die includes a semiconductor die coupled to a die pad. The semiconductor die has a front side containing copper leads, a copper seed layer coupled to the copper leads, and a nickel alloy coating coupled to the copper seed layer. The nickel alloy includes tungsten and cerium (NiWCe). The packaged semiconductor die may also include wire bonds coupled between leads of a lead frame and the copper leads of the semiconductor die. In addition, the packaged semiconductor die may be encapsulated in molding compound. A method for fabricating a packaged semiconductor die. The method includes forming a copper seed layer over the copper leads of the semiconductor die. In addition, the method includes coating the copper seed layer with a nickel alloy. The method also includes singulating the semiconductor wafer to create individual semiconductor die and placing the semiconductor die onto a die pad of a lead frame. In addition the method includes wire bonding the leads of a lead frame to the copper leads of the semiconductor die and then encapsulating the die in molding compound.

A semiconductor device manufacturing method including preparing a semiconductor substrate including an electrode; forming a wire connected to the electrode; forming a first insulating film including a first opening that partially exposes the wire; forming a base portion that is connected to a portion of the wire exposed via the first opening, and that includes a conductor including a recess corresponding to the first opening; forming a solder film on a surface of the base portion; and fusing solder included in the solder film by a first heat treatment, and filling the recess with the fused solder.

Provided here are: an electrically-conductive semiconductor substrate with which a semiconductor circuit is formed; an insulating film deposited on a major surface of the electrically-conductive semi-conductor substrate; and a bonding pad having fixing parts fixed onto the insulating film, side wall parts rising up from the fixing parts, and an electrode part connected to the side wall parts and disposed in parallel to the major surface; wherein the electrode part forms, together with the insulating film, a gap region therebetween, and portions of the electrode part where it is connected to the side wall parts are configured to have at least one of: a positional relationship in which they sandwich therebetween a central portion of the electrode part in its bonding region to be bonded to a bonding wire; and a positional relationship in which they surround the central portion.

A semiconductor device includes a first interconnect structure over first substrate, a first bonding layer over the first interconnect structure, multiple first bonding pads disposed in a first region of the first bonding layer, the first bonding pads having a first pitch, and multiple second bonding pads disposed in a second region of the first bonding layer, the second region extending between a first edge of the first bonding layer and the first region, the second bonding pads having the first pitch, the multiple second bonding pads including multiple pairs of adjacent second bonding pads, wherein the second bonding pads of each respective pair are connected by a first metal line.

A packaged semiconductor die includes a semiconductor die coupled to a die pad. The semiconductor die has a front side containing copper leads, a copper seed layer coupled to the copper leads, and a nickel alloy coating coupled to the copper seed layer. The nickel alloy includes tungsten and cerium (NiWCe). The packaged semiconductor die may also include wire bonds coupled between leads of a lead frame and the copper leads of the semiconductor die. In addition, the packaged semiconductor die may be encapsulated in molding compound. A method for fabricating a packaged semiconductor die. The method includes forming a copper seed layer over the copper leads of the semiconductor die. In addition, the method includes coating the copper seed layer with a nickel alloy. The method also includes singulating the semiconductor wafer to create individual semiconductor die and placing the semiconductor die onto a die pad of a lead frame. In addition the method includes wire bonding the leads of a lead frame to the copper leads of the semiconductor die and then encapsulating the die in molding compound.

A semiconductor package comprising: a first semiconductor chip extending in each of first and second directions that intersect each other; a second semiconductor chip on the first semiconductor chip in a third direction perpendicular to the first and second directions, wherein the second semiconductor chip includes a first area and a second area that is adjacent to and extends around the first area; and a bump structure and a conductive material layer between the first and second semiconductor chips, wherein the conductive material layer is on the bump structure, wherein the bump structure includes a first bump structure overlapping the first area in the third direction, and a second bump structure overlapping the second area in the third direction, wherein the first and second bump structures are spaced apart from each other, and a thickness of the second bump structure is larger than a thickness of the first bump structure.

The invention provide a chip package structure, which includes a first chip and a first hybrid bonding structure. The first chip is connected to another chip through the first hybrid bonding structure. The first hybrid bonding structure includes a first bonding layer. The first bonding layer is disposed on a side away from a substrate of the first chip, and the first bonding layer includes a first insulation material and a plurality of first metal solder pads embedded in the first insulation material. Each of the plurality of first metal solder pads includes a groove structure. A groove bottom of the groove structure is buried in the first insulation material, and a groove opening of the groove structure is exposed to a surface of the first insulation material and is flush with the surface of the first insulation material.

Provided herein is a method for producing hollow contact areas for insertion bonding, formed on a semiconductor substrate comprising a stack of one or more metallization layers on a surface of the substrate. Openings are etched in a dielectric layer by plasma etching, using a resist layer as a mask. The resist layer and plasma etch parameters are chosen to obtain openings with sloped sidewalls having a pre-defined slope, due to controlled formation of a polymer layer forming on the sidewalls of the resist hole and the hollow contact opening formed during etching. According to a preferred embodiment, metal deposited in the hollow contact areas and on top of the dielectric layer is planarized using chemical mechanical polishing, leading to mutually isolated contact areas. The disclosure is also related to components obtainable by the method and to a semiconductor package comprising such components.

A method of producing a semiconductor device includes forming, on a semiconductor substrate comprising a first surface on which an insulating layer covering a wiring structure and a first through via passing through the insulating layer are formed and a second surface opposed to, and facing away from, the first surface, a patterned first insulating film comprising at least one opening therethrough on the second surface, forming a through via hole inwardly of the second surface within which the wiring structure is exposed, by anisotropic dry etching into the second surface side of the semiconductor substrate through the at least one opening in the first insulating film, using a gas mixture containing SF.sub.6, O.sub.2, SiF.sub.4, and at least one of CF.sub.4, Cl.sub.2, BCl.sub.3, CF.sub.3I, and HBr, and forming a second through via in the through via hole.