A ball forming device 50 for forming a ball 43 at a tip of a wire 42 by producing discharge between a torch electrode 48 and the tip of the wire 42, the device includes: a current supply unit 54 configured to supply a ball-forming current between the torch electrode 48 and the tip of the wire 42; and a current control unit 57 configured to control the current supply unit 54, so that a signal of the ball-forming current for a predetermined period includes a first period in which the signal takes a predetermined current value and a second period including a triangle wave. With this, it is possible to provide a ball forming device, a wire-bonding apparatus, and a ball formation method that are capable of suppressing formation of deformed balls.

A palladium-coated copper bonding wire includes: a core material containing copper as a main component; and a palladium layer on the core material, in which a concentration of palladium relative to the entire wire is 1.0 mass % or more and 4.0 mass % or less, and a work hardening coefficient in an amount of change of an elongation rate 2% or more and a maximum elongation rate ? max % or less of the wire, is 0.20 or less.

A light emitting device includes a base member, a light emitting element, a wire, a protective film, first and second resin members, and a light shielding portion. The base member has a conductive member. The wire connects the light emitting element and the conductive member. The protective film covers the conductive member to be spaced apart from a portion of a connecting portion. The first resin member continuously covers at least a portion of each of the protective film, a portion of the conductive member around the connecting portion, and the wire. The first resin member contains first light reflecting particles to reflect light emitted by the light emitting element. The second resin member covers the light emitting element and the first resin member. The light shielding portion is disposed on the base member and disposed on a line connecting the light emitting element and the first resin member.

A methodology and medium for regular and predictable cleaning the support hardware such as capillary tube in semiconductor assembly equipment components, while it is still in manual, semi-automated, and automated assembly are disclosed. The cleaning material may include a cleaning pad layer and one or more intermediate layers that have predetermined characteristics.

A method of interconnecting components of a semiconductor device using wire bonding is presented. The method includes creating a free air ball at a first end of an aluminum wire that has a coating surrounding the aluminum wire, wherein the coating comprises palladium, and wherein the free air ball is substantially free of the coating. The method further includes the step of bonding the free air ball to a bond pad on a semiconductor chip, the bond pad having an aluminum surface layer, wherein the resultant ball bond and the bond pad form a substantially homogenous, aluminum-to-aluminum bond. The method may further include bonding a second, opposing end of the coated-aluminum wire to a bond site separate from the semiconductor chip, the bond site having a palladium surface layer, wherein the second end of the coated-aluminum wire and the bond site form a substantially homogenous, palladium-to-palladium bond.

A method of interconnecting components of a semiconductor device using wire bonding is presented. The method includes creating a free air ball at a first end of an aluminum wire that has a coating surrounding the aluminum wire, wherein the coating comprises palladium, and wherein the free air ball is substantially free of the coating. The method further includes the step of bonding the free air ball to a bond pad on a semiconductor chip, the bond pad having an aluminum surface layer, wherein the resultant ball bond and the bond pad form a substantially homogenous, aluminum-to-aluminum bond. The method may further include bonding a second, opposing end of the coated-aluminum wire to a bond site separate from the semiconductor chip, the bond site having a palladium surface layer, wherein the second end of the coated-aluminum wire and the bond site form a substantially homogenous, palladium-to-palladium bond.

In examples, a package comprises a semiconductor die having a device side and a bond pad on the device side, a conductive terminal exposed to an exterior of the package, and an electrical fuse. The electrical fuse comprises a conductive ball coupled to the bond pad, and a bond wire coupled to the conductive terminal. The bond wire is stitch-bonded to the conductive ball.

A semiconductor device includes a first device having a first pad; a second device having a second pad; and a bonding wire electrically connecting the first device and the second device to each other via the first pad and the second pad. The bonding wire includes: a first bonding structure provided at a first end of the bonding wire, electrically connected to the first device and includes: a first ball bonding region; and a first stitch bonding region; and a second bonding structure provided at a second end opposite of the first end of the bonding wire and electrically connected to the second device.

Wire bonding operations can be facilitated through the use of metal nanoparticle compositions. Both ball bonding and wedge bonding processes can be enhanced in this respect. Wire bonding methods can include providing a wire payout at a first location from a rolled wire source via a dispensation head, contacting a first metal nanoparticle composition and a first portion of the wire payout with a bonding pad, and at least partially fusing metal nanoparticles in the first metal nanoparticle composition together to form an adhering interface between the bonding pad and the first portion of the wire payout. The adhering interface can have a nanoparticulate morphology. Wire bonding systems can include a rolled wire source, a dispensation head configured to provide a wire payout, and an applicator configured to place a metal nanoparticle composition upon at least a portion of the wire payout or upon a bonding pad.

Wire bonding operations can be facilitated through the use of metal nanoparticle compositions. Both ball bonding and wedge bonding processes can be enhanced in this respect. Wire bonding methods can include providing a wire payout at a first location from a rolled wire source via a dispensation head, contacting a first metal nanoparticle composition and a first portion of the wire payout with a bonding pad, and at least partially fusing metal nanoparticles in the first metal nanoparticle composition together to form an adhering interface between the bonding pad and the first portion of the wire payout. The adhering interface can have a nanoparticulate morphology. Wire bonding systems can include a rolled wire source, a dispensation head configured to provide a wire payout, and an applicator configured to place a metal nanoparticle composition upon at least a portion of the wire payout or upon a bonding pad.