A method including stacking a number of silicon dice such that one or more edges of the dice are in vertical alignment, where the one or more edges include a number of connection pads. The method also includes positioning a connecting wire on a substantially perpendicular axis to the one or more edges. The connecting wire includes a number of solder blocks formed thereon. The solder blocks are spaced at intervals associated with a distance between a first set of aligned connection pads on the dice. The connecting wire is positioned such that the solder blocks are in contact with the first set of aligned connection pads. The method also includes applying heat to cause the solder blocks to reflow and physically and electrically couple the connecting wire to the connection pads.

A semiconductor package assembly includes a carrier with a die attach surface and a contact pad separated from the die attach surface, a semiconductor die mounted on the die attach surface, the semiconductor die having a front side metallization that faces away from the die attach surface, an interconnect ribbon attached to the semiconductor die and the contact pad such that the interconnect ribbon electrically connects the front side metallization to the contact pad, and an electrically insulating encapsulant body that encapsulates the semiconductor die and at least part of the interconnect ribbon. The interconnect ribbon includes a layer stack of a first metal layer and a second layer formed on top of the first metal layer. The first metal layer includes a different metal as the second metal layer. The first metal layer faces the front side metallization.

A semiconductor package assembly includes a carrier with a die attach surface and a contact pad separated from the die attach surface, a semiconductor die mounted on the die attach surface, the semiconductor die having a front side metallization that faces away from the die attach surface, an interconnect ribbon attached to the semiconductor die and the contact pad such that the interconnect ribbon electrically connects the front side metallization to the contact pad, and an electrically insulating encapsulant body that encapsulates the semiconductor die and at least part of the interconnect ribbon. The interconnect ribbon includes a layer stack of a first metal layer and a second layer formed on top of the first metal layer. The first metal layer includes a different metal as the second metal layer. The first metal layer faces the front side metallization.

A bonding tool includes a wedge tool that presses a bonding wire against a principal plane of a structure such as an electrode to which the bonding wire is to be bonded. A groove formed in an end portion of a wedge tool body of the wedge tool is inclined along a longitudinal direction of the bonding wire so that a heel side of the groove is closer to the principal plane of the structure than a toe side of the groove. As a result, the wedge tool is inclined at a tilt angle and the bonding wire fits the groove in the end portion of the wedge tool body along the longitudinal direction of the bonding wire. Thus, a corner portion of the wedge tool does not contact the electrode.

A bonding tool includes a wedge tool that presses a bonding wire against a principal plane of a structure such as an electrode to which the bonding wire is to be bonded. A groove formed in an end portion of a wedge tool body of the wedge tool is inclined along a longitudinal direction of the bonding wire so that a heel side of the groove is closer to the principal plane of the structure than a toe side of the groove. As a result, the wedge tool is inclined at a tilt angle and the bonding wire fits the groove in the end portion of the wedge tool body along the longitudinal direction of the bonding wire. Thus, a corner portion of the wedge tool does not contact the electrode.

A chip arrangement including: a chip including a chip back side; a substrate including a surface with a plating; and a zinc-based solder alloy which attaches the chip back side to the plating on the surface of the substrate, the zinc-based solder alloy including, by weight, 1% to 30% aluminum, 0.5% to 20% germanium, and 0.5% to 20% gallium, wherein a balance of the zinc-based solder alloy is zinc.

Systems, methods, and devices for 3D packaging. In some embodiments, a semiconductor package includes a first die and a second die. The first die includes a first bonding pad on a top of the first die and near a first edge of the first die. The second die includes a second bonding pad on a top of the second die and near a second edge of the second die. A pillar is located on the second bonding pad. The first die is mounted on top of the second die such that the first edge is parallel to the second edge and offset from the second edge such that the pillar is exposed. A wire is bonded to a bonding surface of the pillar and bonded to a bonding surface of the first bonding pad.

Systems, methods, and devices for 3D packaging. In some embodiments, a semiconductor package includes a first die and a second die. The first die includes a first bonding pad on a top of the first die and near a first edge of the first die. The second die includes a second bonding pad on a top of the second die and near a second edge of the second die. A pillar is located on the second bonding pad. The first die is mounted on top of the second die such that the first edge is parallel to the second edge and offset from the second edge such that the pillar is exposed. A wire is bonded to a bonding surface of the pillar and bonded to a bonding surface of the first bonding pad.

A capillary for performing ball bonding includes a body defining a lumen, a first blade defined in a lower tip of the body, and a second blade defined in the lower tip of the body for increasing reliability of a ball bonding procedure performed using the capillary.

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.