Formation of bonding wire vertical interconnects

Abstract

A wire bonding method, comprising the steps of: extending a length of bonding wire from a capillary to form a wire tail; deforming a point on the wire tail to form a weakened portion between the wire tail and a remainder of the bonding wire retained within the capillary; and retracting at least a portion of the wire tail including the weakened portion into the capillary prior to bonding the wire tail to at least one of a bonding pad and a substrate.

Claims

1. A wire bonding method, comprising the steps of: extending a length of bonding wire from a capillary to form a wire tail; deforming a point on the wire tail to form a weakened portion between an unweakened portion of the wire tail and a remainder of the bonding wire retained within the capillary; and retracting at least a portion of the wire tail including the weakened portion into the capillary prior to bonding the wire tail to at least one of a bonding pad and a substrate.

2. The method of claim 1, wherein the wire tail has a free end distal from the capillary and the weakened portion is proximate the capillary.

3. The method of claim 1, wherein the step of deforming comprises pressing the wire tail with the capillary against at least one of the substrate and the bonding pad.

4. The method of claim 1, wherein the step of deforming comprises pressing the point on the wire tail against at least one of the substrate and the bonding pad.

5. The method of claim 2, wherein the step of deforming comprises translating the wire tail towards at least one of the substrate and the bonding pad to contact the free end of the wire tail against at least one of the substrate and the bonding pad, continued translation of the wire tail causing the free end to move over a surface of at least one of the substrate and the bonding pad out of axial alignment with the remainder of the bonding wire retained within the capillary.

6. The method of claim 1, wherein the step of deforming comprises displacing the capillary in a displacement direction towards at least one of the substrate and the bonding pad while translating the capillary in a direction transverse the displacement direction.

7. The method of claim 1, wherein the step of deforming comprises compressing a cross section of the wire tail to form the weakened portion.

8. The method of claim 1, wherein the step of deforming further comprises the step of forming the wire tail around a tip of the capillary.

9. The method of claim 1, wherein the step of retracting further includes the step of aligning the wire tail with respect to the remainder of the bonding wire retained within the capillary prior to bonding.

10. The method of claim 1, comprising forming a bond ball on the free end of the wire tail prior to bonding.

11. The method of claim 10, comprising displacing the bond ball to bond with the bond pad to form a ball wire bond.

12. The method of claim 6, comprising repeatedly translating the capillary in directions transverse the displacement direction to further weaken the weakened portion.

13. The method of claim 12, comprising aligning an opening of the capillary through which the bonded wire extends proximate the weakened portion while repeatedly translating the capillary in the direction transverse the displacement direction to further weaken the weakened portion.

14. The method of claim 1, comprising displacing the remainder of the bonding wire and gripping the remainder of the bonding wire to detach it from a ball wire bond at the weakened portion.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Embodiments of the present invention will now be described, by way of example only, with reference to the accompanying drawings, in which:

(2) FIG. 1 illustrates the main components of a wire bonding apparatus used to form wire interconnects according to one embodiment; and

(3) FIGS. 2 to 9 illustrate operation of the wire bonding apparatus when making wire bond interconnects according to the preferred embodiment of the invention.

(4) In the drawings, like parts are denoted by like reference numerals.

DETAILED DESCRIPTION

(5) Before discussing embodiments of the invention in any more detail, first an overview will be provided. In one embodiment, a length of wire is released from a capillary and the unbonded wire is pre-cut (deformed, typically by compression to form a wedge) at a first bond position. The wire is then retracted leaving a wire tail, and a free-air ball is formed at the wire tail in order to make the first bond. After the first bond is made, the capillary is lifted and the wire is broken.

(6) FIG. 1 illustrates the main components of a wire bonding apparatus 100 used to form wire interconnects according to one embodiment. Other components of the wire bonding apparatus 100 have been omitted to improve clarity. A capillary 103 is provided which is axially-aligned with wire holding mechanisms, such as a proximal wire clamp 102 and a distal wire clamp 101. A continuous length of bonding wire 105 provided from a bonding wire reel (not shown) passes through the wire clamps 101, 102 as well as through the capillary 103. The bonding wire 105 is free to pass through the capillary 103, but the wire clamps 101, 102 are operable to independently clamp or unclamp the bonding wire 105. The distal wire clamp 101 has a generally fixed height, whereas the proximal wire clamp 102 is independently displaceable along the axial direction of the bonding wire 105, as will be explained in more detail below.

(7) As can be seen in FIG. 1, the bonding apparatus 100 is positioned above a bonding location where a wire interconnect is to be located such as, for example, above a bonding pad 202 on the substrate 201. The distal wire clamp 101 is not gripping the bonding wire 105, but the proximal wire clamp 102 is gripping the bonding wire 105. A length of bonding wire 105 has been passed through the capillary 103 (which is located at a reset level), such that the bonding wire 105 extends from a tip 106 of the capillary 103 to form a wire tail 104. Such wire tail 104 may be obtained, for instance, from the execution of a previous wire bonding operation. Hence, a wire tail 104 is located above the bonding pad 202 in readiness to be conveyed in direction A towards the bonding pad 202.

(8) Turning now to FIG. 2, the proximal wire clamp 102 and the capillary 103 move together towards the substrate 201 generally in the direction A. The distal wire clamp 101 remains unclamped to enable the wire to move. As illustrated in FIG. 2, the proximal wire clamp 102 and the capillary 103 move towards the bonding pad 202 along a curved trajectory by translating the capillary 103 in a direction transverse to the direction A during movement of the capillary 103 to facilitate bending of the wire tail 104 when the wire tail 104 contacts the substrate 201.

(9) Thus, when a free end 107 of the wire tail 104 extending out of the tip 106 contacts the substrate 201, such contact causes the wire tail 104 to bend and lie generally along the surface of the substrate 201. The mechanical properties of the bonding wire 105 are such that it is generally prone to bend sharply about the tip 106 with the tail 104 remaining generally straight. Hence, a tight elbow bend 110 occurs between the wire tail 104 and the remainder of the bonding wire 105 within the capillary 103. This leads to a generally right-angled bend in the vicinity of the tip 106, with the elbow bend 110 being formed around and following the shape of the tip 106. The tip 106 is chamfered and shaped to define an annular projection 108 which helps shape a corner bend.

(10) Optionally, the orientation of the capillary 103 may be altered off-axis to help the wire tail 104 contact the substrate 201 at a more oblique angle to facilitate bending.

(11) Continued movement of the capillary 103 in the direction A causes the annular projection 108 to deform the bonding wire 105 by creating an indentation, compression, recess or wedge in the vicinity of the annular projection 108 to provide a weakened portion or point between the wire tail 104 and the remaining bonding wire 105 within the capillary 103. In other words, the capillary 103 moves down to bend and deform the wire tail using cherry-pit bonding. Alternatively, other than using the annular projection 108 of the capillary 103, deformation of the bonding wire 105 may also be achieved by the introduction of an external tool (not shown).

(12) Thus, as can be seen in FIG. 2, the wire tail 104 has been bent out of alignment with the remaining bonding wire 105 within the capillary 103. Furthermore, a weakened portion therebetween has been created.

(13) As can be seen in FIG. 3, the distal wire clamp 101 remains unclamped and the capillary 103 and the proximal wire clamp 102 move together in the direction B, away from the substrate 202. This elevates the wire tail 104 away from the substrate 202 and the capillary returns to the reset level.

(14) As can be seen in FIG. 4, the distal wire clamp 101 now clamps the bonding wire 105 and the proximal wire clamp 102 unclamps the bonding wire 105. The distal wire clamp 101 is operative to hold onto the bonding wire while the proximal wire clamp 102 and the capillary 103 are lowered in direction A away from the distal wire clamp 101. This causes the wire tail 104 to be at least partially received or drawn back within the capillary 103. In particular, the weakened portion on the elbow bend 110 is withdrawn into the capillary 103 and as it does the wire tail 104 is re-straightened to align with the remainder of the bonding wire 105. Accordingly, the bonding wire is restored to the configuration shown in FIG. 1 but now with a wire tail 104 formed with a desired length and with the weakened portion located within the capillary 103.

(15) Turning now to FIG. 5, a distal portion of the wire tail 104 protruding from the tip 106 has a bond ball 501 formed using conventional techniques. The distal wire clamp 101 unclamps and the proximal wire clamp 102 clamps the bonding wire 105. The proximal wire clamp 102 together with the capillary 103 then moves in the direction A towards the bonding pad 202 on the substrate 201.

(16) As can be seen in FIG. 6, the bond ball 501 makes contact with the bonding pad 202 to form a wire bond. The proximal wire clamp 102 then unclamps the bonding wire 105.

(17) As can be seen in FIG. 7, the distal wire clamp 101 clamps the bonding wire 105 to prevent it moving while the proximal wire clamp 102, together with the capillary 103, move back up along the bonding wire in the direction B. Hence, the capillary 103 is retracted back along the bonding wire 105 leaving the wire tail 104 bonded to the bonding pad 202, with the weakened portion 120 between the wire tail 104 and the remainder of the bonding wire 105. When the capillary 103 is at the position of the weakened portion 120, the capillary 103 may be further translated repeatedly in directions transverse to the direction B to help further weaken the weakened portion 120.

(18) Thereafter, the proximal wire clamp 102 together with the capillary 103 are further moved up to form a wire tail 104 of a required length for conducting subsequent wire bonding operations.

(19) As can be seen in FIG. 8, the proximal wire clamp 102 then clamps the bonding wire 105 and the proximal wire clamp 102, together with the capillary 103 move further in direction B. This movement causes the remainder of the bonding wire 105 to move while the wire tail 104 is retained on the bonding pad 202 by the ball wire bond. This causes the wire to break at the weakened portion 120, leaving the wire tail 104 in place in a vertical orientation.

(20) As can be seen in FIG. 9, this process is repeated with adjacent wire tails 104 being bonded at different positions on the substrate 201.

(21) As would be appreciated, unlike in existing approaches, the wire tails 104 are not curved along their length since the wire tails 104 have never been bent as a arching wire between two points on the substrate 201. Also, the sharp elbow bend 110 formed as shown in FIG. 2 is further straightened as shown in FIG. 4 prior to bonding occurring. Furthermore, because the wire tail 104 can be formed and bent at any single location, rather than having to form a arching wire between two locations, the limitation on bonding on substrates that have obstacles around the bond point which obstruct the making of the deformation at a second point around the bond point can be avoided. Moreover, as fewer translational movements are required, vertical interconnect orientation accuracy is increased. Neck stress on the wire bond can also be avoided since it is unnecessary to create a bend in a neck of the wire bond after wire bonding in order to form the weakened portion 120.

(22) Embodiments experience no neck damage of the wire tails unlike that observed with conventional approaches. The wire tail straightness is also improved compared to conventional approaches. The accuracy of wire tail placement (specifically the X&Y offset in orthogonal directions transverse to the displacement direction A/B) may be improved by around 50% compared to conventional approaches. The wire cutting position and first bond position can be the same, which obviates the need for additional space to cut/deform the wire. A wider range of different wire tail heights is therefore possible compared to conventional approaches.

(23) Although the present invention has been described in considerable detail with reference to certain embodiments, other embodiments are possible.

(24) Therefore, the spirit and scope of the appended claims should not be limited to the description of the embodiments contained herein.