A semiconductor device according to the present invention includes a semiconductor chip, an electrode pad made of a metal material containing aluminum and formed on a top surface of the semiconductor chip, an electrode lead disposed at a periphery of the semiconductor chip, a bonding wire having a linearly-extending main body portion and having a pad bond portion and a lead bond portion formed at respective ends of the main body portion and respectively bonded to the electrode pad and the electrode lead, and a resin package sealing the semiconductor chip, the electrode lead, and the bonding wire, the bonding wire is made of copper, and the entire electrode pad and the entire pad bond portion are integrally covered by a water-impermeable film.

A semiconductor device according to the present invention includes a semiconductor chip, an electrode pad made of a metal material containing aluminum and formed on a top surface of the semiconductor chip, an electrode lead disposed at a periphery of the semiconductor chip, a bonding wire having a linearly-extending main body portion and having a pad bond portion and a lead bond portion formed at respective ends of the main body portion and respectively bonded to the electrode pad and the electrode lead, and a resin package sealing the semiconductor chip, the electrode lead, and the bonding wire, the bonding wire is made of copper, and the entire electrode pad and the entire pad bond portion are integrally covered by a water-impermeable film.

In a copper alloy bonding wire for semiconductor devices, the bonding longevity of a ball bonded part under high-temperature and high-humidity environments is improved. The copper alloy bonding wire for semiconductor devices includes in total 0.03% by mass or more to 3% by mass or less of at least one or more kinds of elements selected from Ni, Zn, Ga, Ge, Rh, In, Ir, and Pt (first element), with the balance Cu and inevitable impurities. The inclusion of a predetermined amount of the first element suppresses production of an intermetallic compound susceptible to corrosion under high-temperature and high-humidity environments at the wire bonding interface and improves the bonding longevity of a ball bonded part.

A semiconductor device including an element isolation in a trench formed in an upper surface of a semiconductor substrate, a trench isolation including a void in a trench directly under the element isolation, and a Cu wire with Cu ball connected to a pad on the semiconductor substrate, is formed. The semiconductor device has a circular trench isolation arrangement prohibition region that overlaps the end portion of the Cu ball in plan view, and the trench isolation is separated from the trench isolation arrangement prohibition region in plan view.

A semiconductor device includes a semiconductor part, first and second electrodes, and first and second protective films. The first electrode is provided on the semiconductor part. The first protective film is provided on the semiconductor part and covers an outer edge of the first electrode. The second electrode is provided on the first electrode. The second electrode includes an outer edge partially covering the first protective film. The second protective film is provided on the semiconductor part and covers the first protective film and the outer edge of the second electrode.

A method for preparing a semiconductor device includes providing an integrated circuit die having a bond pad. The bond pad includes aluminum (Al). The method also includes etching a top portion of the bond pad to form a recess, and bonding a wire bond to the recess in the bond pad. The wire bond includes copper (Cu).

A method of packaging a semiconductor device includes: bonding a ball at an end of a bond wire to a bond pad of a semiconductor device die in an aperture of a shielding layer of the semiconductor device; and sealing the part of the bond pad exposed by the aperture of the shielding layer by deforming the ball of the bond wire to fill the aperture of the shielding layer. The aperture of the shielding layer includes an edge wall, and exposes a part of the bond pad. The shielding layer covers a remaining part of the bond pad. The aperture of the shielding layer is completely filled with the ball of the bond wire, thereby deforming the edge wall of the shielding layer.

The manufacturing method of a semiconductor device can improve the mechanical strength of a pad more than before, and suppress the occurrence of a crack. The manufacturing method of a semiconductor device includes: forming a first pad constituted by a first metal layer; forming an insulating layer on the first pad; providing an opening portion in the insulating layer by removing the insulating layer on at least a partial region of the first pad; forming a second pad constituted by a second metal layer in the opening portion of the insulating layer so as to have a film thickness that is smaller than the film thickness of the insulating layer; and forming a third pad constituted by a third metal layer on the second pad.

A semiconductor device has a semiconductor die and substrate with a plurality of stud bumps formed over the semiconductor die or substrate. The stud bumps include a base portion and stem portion extending from the base portion. The stud bumps include a non-fusible material or fusible material. The semiconductor die is mounted to the substrate with the stud bumps electrically connecting the semiconductor die to the substrate. A width of the base portion is greater than a mating conductive trace formed on the substrate. Alternatively, a vertical interconnect structure, such as a conductive column, is formed over the semiconductor die or substrate. The conductive column can have a tapered sidewall or oval cross sectional area. An underfill material is deposited between the semiconductor die and substrate. The semiconductor die includes a flexible property. The vertical interconnect structure includes a flexible property. The substrate includes a flexible property.

A semiconductor device has a semiconductor die and substrate with a plurality of stud bumps formed over the semiconductor die or substrate. The stud bumps include a base portion and stem portion extending from the base portion. The stud bumps include a non-fusible material or fusible material. The semiconductor die is mounted to the substrate with the stud bumps electrically connecting the semiconductor die to the substrate. A width of the base portion is greater than a mating conductive trace formed on the substrate. Alternatively, a vertical interconnect structure, such as a conductive column, is formed over the semiconductor die or substrate. The conductive column can have a tapered sidewall or oval cross sectional area. An underfill material is deposited between the semiconductor die and substrate. The semiconductor die includes a flexible property. The vertical interconnect structure includes a flexible property. The substrate includes a flexible property.