A semiconductor package includes a metallic pad and leads spaced from the metallic pad by a gap, the metallic pad including a roughened surface. The semiconductor package further includes a semiconductor die including bond pads, and an adhesive between the roughened surface of the metallic pad and the semiconductor die, therein bonding the semiconductor die to the metallic pad, wherein the adhesive includes a resin. The metallic pad further includes a groove surrounding the semiconductor die on the roughened surface, the groove having a surface roughness less than a surface roughness of the roughened surface of the metallic pad.

A semiconductor package includes a metallic pad and leads, a semiconductor die attached to the metallic pad, the semiconductor die including an active side with bond pads opposite the metallic pad, a wire bond extending from a respective bond pad of the semiconductor die to a respective lead of the leads, a heat spreader over the active side of the semiconductor die with a gap separating the active side of the semiconductor die from the heat spreader, an electrically insulating material within the gap and in contact with the active side of the semiconductor die and the heat spreader; and mold compound covering the semiconductor die and the wire bond, and partially covering the metallic pad and the heat spreader, with the metallic pad exposed on a first outer surface of the semiconductor package and with the heat spreader exposed on a second outer surface of the semiconductor package.

A semiconductor package includes a metallic pad and leads, a semiconductor die attached to the metallic pad, the semiconductor die including an active side with bond pads opposite the metallic pad, a wire bond extending from a respective bond pad of the semiconductor die to a respective lead of the leads, a heat spreader over the active side of the semiconductor die with a gap separating the active side of the semiconductor die from the heat spreader, an electrically insulating material within the gap and in contact with the active side of the semiconductor die and the heat spreader; and mold compound covering the semiconductor die and the wire bond, and partially covering the metallic pad and the heat spreader, with the metallic pad exposed on a first outer surface of the semiconductor package and with the heat spreader exposed on a second outer surface of the semiconductor package.

A semiconductor package includes a pad and leads having a planar profile shaped from a planar base metal, a semiconductor die attached to the pad, a wire bond extending from the semiconductor die to a respective lead, and mold compound covering the semiconductor die, the wire bond, and a first portion of the respective lead, wherein a second portion of the respective lead extends beyond the mold compound. A shape of the respective lead within the planar profile includes a notch indented relative to a first elongated side of the shape of the respective lead and a protrusion protruding outwardly relative to a second elongated side of the shape of the respective lead. The notch and the protrusion are each partially covered by the mold compound and partially outside the mold compound.

A semiconductor package includes a metallic pad and leads spaced from the metallic pad by a gap, the metallic pad including a roughened surface. The semiconductor package further includes a semiconductor die including bond pads, and an adhesive between the roughened surface of the metallic pad and the semiconductor die, therein bonding the semiconductor die to the metallic pad, wherein the adhesive includes a resin. The metallic pad further includes a groove surrounding the semiconductor die on the roughened surface, the groove having a surface roughness less than a surface roughness of the roughened surface of the metallic pad.

A semiconductor package includes a metallic pad and leads spaced from the metallic pad by a gap, the metallic pad including a roughened surface. The semiconductor package further includes a semiconductor die including bond pads, and an adhesive between the roughened surface of the metallic pad and the semiconductor die, therein bonding the semiconductor die to the metallic pad, wherein the adhesive includes a resin. The metallic pad further includes a groove surrounding the semiconductor die on the roughened surface, the groove having a surface roughness less than a surface roughness of the roughened surface of the metallic pad.

It is an object to provide a Cu alloy bonding wire for a semiconductor device that can satisfy required performance in high-density LSI applications. In the Cu alloy bonding wire for a semiconductor device according to the present invention, each of abundance ratios of crystal orientations <100>, <110> and <111> having an angular difference of 15 degrees or less from a direction perpendicular to one plane including a wire center axis out of crystal orientations on a wire surface is 3% or more and less than 27% in average area percentage.

It is an object to provide a Cu alloy bonding wire for a semiconductor device that can satisfy required performance in high-density LSI applications. In the Cu alloy bonding wire for a semiconductor device according to the present invention, each of abundance ratios of crystal orientations <100>, <110> and <111> having an angular difference of 15 degrees or less from a direction perpendicular to one plane including a wire center axis out of crystal orientations on a wire surface is 3% or more and less than 27% in average area percentage.

It is an object to provide a Cu alloy bonding wire for a semiconductor device that can satisfy required performance in high-density LSI applications. In the Cu alloy bonding wire for a semiconductor device according to the present invention, each of abundance ratios of crystal orientations <100>, <110> and <111> having an angular difference of 15 degrees or less from a direction perpendicular to one plane including a wire center axis out of crystal orientations on a wire surface is 3% or more and less than 27% in average area percentage.

It is an object to provide a Cu alloy bonding wire for a semiconductor device that can satisfy required performance in high-density LSI applications. In the Cu alloy bonding wire for a semiconductor device according to the present invention, each of abundance ratios of crystal orientations <100>, <110> and <111> having an angular difference of 15 degrees or less from a direction perpendicular to one plane including a wire center axis out of crystal orientations on a wire surface is 3% or more and less than 27% in average area percentage.