A device includes a semiconductor die including a via, a layer of titanium tungsten (TiW) in contact with the via, and a copper pillar including a top portion and a bottom portion. The bottom portion is in contact with the layer of TiW. The copper pillar includes interdiffused zinc within the bottom portion.

Disclosed is a semiconductor device comprising a semiconductor substrate, an under-bump pattern on the semiconductor substrate and including a first metal, a bump pattern on the under-bump pattern, and an organic dielectric layer on the semiconductor substrate and in contact with a sidewall of the bump pattern. The bump pattern includes a support pattern in contact with the under-bump pattern and having a first width, and a solder pillar pattern on the support pattern and having a second width. The first width is greater than the second width. The support pattern includes at least one of a solder material and an intermetallic compound (IMC). The intermetallic compound includes the first metal and the solder material.

Provided is a method for producing a joined body, the method including a first step of preparing a laminated body which includes a first member having a metal pillar provided on a surface thereof, a second member having an electrode pad provided on a surface thereof, and a joining material provided between the metal pillar and the electrode pad and containing metal particles and an organic compound, and a second step of heating the laminated body to sinter the joining material at a predetermined sintering temperature, in which the joining material satisfies the condition of the following Formula (I):
(M.sub.1−M.sub.2)/M.sub.1×100≥1.0  (I)
[in Formula (I), M.sub.1 represents a mass of the joining material when a temperature of the joining material reaches the sintering temperature in the second step, and M.sub.2 represents a non-volatile content in the joining material.]

Embodiments relate to the design of a device capable of maintaining the alignment an interconnect by resisting lateral forces acting on surfaces of the interconnect. The device comprises a first body comprising a first surface with a nanoporous metal structure protruding from the first surface. The device further comprises a second body comprising a second surface with a locking structure to resist a lateral force between the first body and the second body during or after assembly of the first body and the second body.

Embodiments relate to the design of a device capable of maintaining the alignment an interconnect by resisting lateral forces acting on surfaces of the interconnect. The device comprises a first body comprising a first surface with a nanoporous metal structure protruding from the first surface. The device further comprises a second body comprising a second surface with a locking structure to resist a lateral force between the first body and the second body during or after assembly of the first body and the second body.

Disclosed is a semiconductor device comprising a semiconductor substrate, an under-bump pattern on the semiconductor substrate and including a first metal, a bump pattern on the under-bump pattern, and an organic dielectric layer on the semiconductor substrate and in contact with a sidewall of the bump pattern. The bump pattern includes a support pattern in contact with the under-bump pattern and having a first width, and a solder pillar pattern on the support pattern and having a second width. The first width is greater than the second width. The support pattern includes at least one of a solder material and an intermetallic compound (IMC). The intermetallic compound includes the first metal and the solder material.

In some examples, a package comprises a die and a redistribution layer coupled to the die. The redistribution layer comprises a metal layer, a brass layer abutting the metal layer, and a polymer layer abutting the brass layer.

A wafer-level pulling method includes securing a top holder to a plurality of chips; and securing a bottom holder to a wafer, wherein the plurality of chips are bonded to the wafer by a plurality of solder bumps. The wafer-level pulling method further includes softening the plurality of solder bumps; and stretching the plurality of softened solder bumps.

An integrated circuit device may include a multi-material toothed bond pad including (a) an array of vertically-extending teeth formed from a first material, e.g., aluminum, and (b) a fill material, e.g., silver, at least partially filling voids between the array of teeth. The teeth may be formed by depositing and etching aluminum or other suitable material, and the fill material may be deposited over the array of teeth and extending down into the voids between the teeth, and etched to expose top surfaces of the teeth. The array of teeth may collectively define an abrasive structure. The multi-material toothed bond pad may be bonded to another bond pad, e.g., using an ultrasonic or thermosonic bonding process, during which the abrasive teeth may abrade, break, or remove unwanted native oxide layers formed on the respective bond pad surfaces, to thereby create a direct and/or eutectic bonding between the bond pads.

An integrated circuit device may include a multi-material toothed bond pad including (a) an array of vertically-extending teeth formed from a first material, e.g., aluminum, and (b) a fill material, e.g., silver, at least partially filling voids between the array of teeth. The teeth may be formed by depositing and etching aluminum or other suitable material, and the fill material may be deposited over the array of teeth and extending down into the voids between the teeth, and etched to expose top surfaces of the teeth. The array of teeth may collectively define an abrasive structure. The multi-material toothed bond pad may be bonded to another bond pad, e.g., using an ultrasonic or thermosonic bonding process, during which the abrasive teeth may abrade, break, or remove unwanted native oxide layers formed on the respective bond pad surfaces, to thereby create a direct and/or eutectic bonding between the bond pads.