Apparatus and method for tool mark free stich bonding. In some embodiments, a method for wire bonding can include feeding a wire through a capillary tip and attaching a first end of the wire to a first location, thereby forming a ball bond. The method can further include moving the capillary tip towards a second location while the wire feeds out of the capillary tip. The method can further include attaching a second end of the wire to the second location while preventing contact between the capillary tip and the second location, thereby forming a stitch bond without a tool mark at the second location.

Disclosed are a semiconductor device and a stacked semiconductor package. The semiconductor device may include a semiconductor chip and a plurality of chip pads disposed on the semiconductor chip in a second horizontal direction perpendicular to a first horizontal direction. The plurality of chip pads may include: a first chip pad connected to a wire extending in the first horizontal direction, when seen from the top; and a second chip pad connected to a diagonal wire extending in a direction at an angle to the first and second horizontal directions, when seen from the top. The width of the first chip pad in the second horizontal direction may be smaller than the width of the second chip pad in the second horizontal direction.

It is an object to enable a non-destructive inspection of reliability of a bonding part and enabling an accurate inspection. A wedge tool includes: a groove which is formed along a direction of an ultrasonic vibration in a tip portion and in which a bonding wire is disposed in a wedge bonding; a first planar surface and a second planar surface disposed on both sides of the groove; and at least one convex portion formed away from the groove in at least one of the first planar surface and the second planar surface, wherein the bonding wire comes in contact with the convex portion by a deformation of the bonding wire in a bonding part of the bonding wire and a bonded object bonded to each other by a wedge bonding.

According to one embodiment, a semiconductor device includes a first electrode, a second electrode, and a wire extending between the first electrode and the second electrode. The wire includes a first conductor in contact with the first electrode and the second electrode, and a second conductor that is provided inside the first conductor and has no contact with the first electrode and the second electrode.

A semiconductor device A1 includes a substrate 3, a conductive section 5 formed on the substrate 3 and including a conductive material, a lead 1A located on the substrate 3, a semiconductor chip 4A located on the lead 1A, a control chip 4G located on the substrate 3 and electrically connected to the conductive section 5 and the semiconductor chip 4A for controlling an operation of the semiconductor chip 4A, and a resin 7 covering the semiconductor chip 4A, the control chip 4G, at least a part of the substrate 3 and a part of the lead 1A. This configuration contributes to achieving a higher level of integration of the semiconductor device.

A semiconductor device A1 includes a substrate 3, a conductive section 5 formed on the substrate 3 and including a conductive material, a lead 1A located on the substrate 3, a semiconductor chip 4A located on the lead 1A, a control chip 4G located on the substrate 3 and electrically connected to the conductive section 5 and the semiconductor chip 4A for controlling an operation of the semiconductor chip 4A, and a resin 7 covering the semiconductor chip 4A, the control chip 4G, at least a part of the substrate 3 and a part of the lead 1A. This configuration contributes to achieving a higher level of integration of the semiconductor device.

An apparatus comprising: a die stack comprising at least one die pair, the at least one die pair having a first die over a second die, the first die and the second die both having a first surface and a second surface, the second surface of the first die over the first surface of the second die; and an adhesive film between the first die and the second die of the at least one die pair; wherein the adhesive film comprises an insulating layer and a conductive layer, the insulating layer adhering to the second surface of the first die and the conductive layer adhering to the first surface of the second die.

An apparatus comprising: a die stack comprising at least one die pair, the at least one die pair having a first die over a second die, the first die and the second die both having a first surface and a second surface, the second surface of the first die over the first surface of the second die; and an adhesive film between the first die and the second die of the at least one die pair; wherein the adhesive film comprises an insulating layer and a conductive layer, the insulating layer adhering to the second surface of the first die and the conductive layer adhering to the first surface of the second die.

A multifaceted capillary that can be used in a wire-bonding machine to create a multi-segment wire-bond is disclosed. The multifaceted capillary is shaped to apply added pressure and thickness to an outer segment of the multi-segment wire-bond that is closest to the wire loop. The added pressure eliminates a gap under a heel portion of the multi-segment wire-bond and the added thickness increases a mechanical strength of the heel portion. As a result, a pull test of the multi-segment wire-bond may be higher than a single-segment wire-bond and the multi-segment wire-bond may resist cracking, lifting, or breaking.

An electrical circuit in a semiconductor package may include a wire connected at each end by a bond point formed using a wire-bonding machine. When a connection point (e.g., a die pad) has a very small dimension, the wire used for the circuit may be required to have a similarly small diameter. This small diameter can lead to a weak bond point, especially in bonds that include a heel portion. The heel portion is a transition region of the bond point that may have less strength (e.g., as measure by a pull-test) than other portions of the bond point and/or may be exposed to more forces than other portions of the bond point. Accordingly, a capping-bond point may be applied to the bond point to strengthen the bond point by clamping the heel portion and shielding it from forces that could cause cracks.