A wedge bonding tool is provided. The wedge bonding tool includes a body portion including a tip portion, the tip portion terminating at a working end of the wedge bonding tool. The tip portion includes (i) two opposing walls, and (ii) an adjoining surface between the two opposing walls. The adjoining surface includes a flat area. The two opposing walls and the flat area define a groove configured to receive a wire. The flat area has a width of at least 20% of a width of the groove at the working end.

An ultra-fine pitch wedge bonding tool and method for its manufacture are disclosed. The wedge tool is formed with a foot width calculated to enable accurate bonding of wires separated at an ultra-fine pitch. The wedge tool is made out of a tungsten carbide alloy having characteristics conforming to specified constraints that lead to improved performance and enable the use of thicker wire. A pocket is formed at the tip of the wedge tool and a wire feeding hole is formed from the rear side of the tool and exiting inside the pocket, at an elevation above the bonding foot. Side walls are provided on both sides of the pocket to guide the wire exiting the feed hole inside the pocket towards the bonding foot.

A method of forming a wire interconnect structure includes the steps of: (a) forming a wire bond at a bonding location on a substrate using a wire bonding tool; (b) extending a length of wire, continuous with the wire bond, to a position above the wire bond; (c) moving the wire bonding tool to contact the length of wire, at a position along the length of wire, to partially sever the length of wire at the position along the length of wire; and (d) separating the length of wire from a wire supply at the position along the length of wire, thereby providing a wire interconnect structure bonded to the bonding location.

The invention relates to an electrical element having at least one functional region and a contact surface, wherein a connecting element is arranged on the contact surface, wherein the connecting element comprises a stranded wire coated with sintered material, wherein the stranded wire is connected, in particular sintered, to the contact surface by a sintered material. Furthermore, the invention relates to a method for producing the electrical element according to the invention.

A method of forming a wire interconnect structure includes the steps of: (a) forming a wire bond at a bonding location on a substrate using a wire bonding tool; (b) extending a length of wire, continuous with the wire bond, to a position above the wire bond; (c) moving the wire bonding tool to contact the length of wire, at a position along the length of wire, to partially sever the length of wire at the position along the length of wire; and (d) separating the length of wire from a wire supply at the position along the length of wire, thereby providing a wire interconnect structure bonded to the bonding location.

A wedge bonding tool is provided. The wedge bonding tool includes a body portion and a tip portion at a terminal end of the body portion. The tip portion includes a groove surface defining a groove. The groove is configured to receive a wire during a wire bonding operation. The groove surface includes a plurality of laser scribed recesses.