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.

A non alpha controlled plating bath including Tin species and a trace amount of Polonium species is utilized in a plating tool. The plating tool includes a Polonium filter element to remove Polonium species from the plating bath to selectively plate Tin upon a plating cathode. The filter may include a Titanium inner portion surrounding by a stannic oxide exterior. The filter may reduce the Polonium species by having the polonium absorb and then enter within the stannic oxide matrix. The filter may be located within the plating tool reservoir or filter housing. The filter may be fabricated by forming Tin upon a Titanium backbone and converting the Tin to stannic oxide.

Embodiments of the disclosure provide an interconnect structure including: a first die having a first surface and an opposing second surface, and a groove within first surface of the first die; an adhesive dielectric layer mounted to the opposing second surface of the first die; a second die having a first surface mounted to the adhesive dielectric layer, and an opposing second surface, wherein the adhesive dielectric layer is positioned directly between the first and second dies; and a through-semiconductor via (TSV) including a first TSV metal extending from the first surface of the first die to the adhesive dielectric layer, and a second TSV metal substantially aligned with the first TSV metal and extending from the adhesive dielectric layer to the opposing second surface of the second die, wherein the TSV includes a metal-to-metal bonding interface between the first and second TSV metals within the adhesive dielectric layer.

Embodiments of the disclosure provide an interconnect structure including: a first die having a first surface and an opposing second surface, and a groove within first surface of the first die; an adhesive dielectric layer mounted to the opposing second surface of the first die; a second die having a first surface mounted to the adhesive dielectric layer, and an opposing second surface, wherein the adhesive dielectric layer is positioned directly between the first and second dies; and a through-semiconductor via (TSV) including a first TSV metal extending from the first surface of the first die to the adhesive dielectric layer, and a second TSV metal substantially aligned with the first TSV metal and extending from the adhesive dielectric layer to the opposing second surface of the second die, wherein the TSV includes a metal-to-metal bonding interface between the first and second TSV metals within the adhesive dielectric layer.

A non alpha controlled plating bath including Tin species and a trace amount of Polonium species is utilized in a plating tool. The plating tool includes a Polonium filter element to remove Polonium species from the plating bath to selectively plate Tin upon a plating cathode. The filter may include a Titanium inner portion surrounding by a stannic oxide exterior. The filter may reduce the Polonium species by having the polonium absorb and then enter within the stannic oxide matrix. The filter may be located within the plating tool reservoir or filter housing. The filter may be fabricated by forming Tin upon a Titanium backbone and converting the Tin to stannic oxide.

A non alpha controlled plating bath including Tin species and a trace amount of Polonium species is utilized in a plating tool. The plating tool includes a Polonium filter element to remove Polonium species from the plating bath to selectively plate Tin upon a plating cathode. The filter may include a Titanium inner portion surrounding by a stannic oxide exterior. The filter may reduce the Polonium species by having the polonium absorb and then enter within the stannic oxide matrix. The filter may be located within the plating tool reservoir or filter housing. The filter may be fabricated by forming Tin upon a Titanium backbone and converting the Tin to stannic oxide.

A non alpha controlled plating bath including Tin species and a trace amount of Polonium species is utilized in a plating tool. The plating tool includes a Polonium filter element to remove Polonium species from the plating bath to selectively plate Tin upon a plating cathode. The filter may include a Titanium inner portion surrounding by a stannic oxide exterior. The filter may reduce the Polonium species by having the polonium absorb and then enter within the stannic oxide matrix. The filter may be located within the plating tool reservoir or filter housing. The filter may be fabricated by forming Tin upon a Titanium backbone and converting the Tin to stannic oxide.

A semiconductor chip includes an epitaxial semiconductor layer sequence, a solder layer arranged over a back side face of the epitaxial semiconductor layer sequence, a buffer layer arranged between the back side face of the epitaxial semiconductor layer sequence and the solder layer. The buffer layer includes a porous and/or rough metal.

A semiconductor device and a manufacturing method thereof. The semiconductor device includes a semiconductor substrate (300) provided with a plurality of pads (301), columnar electrodes on the pads (301) and a solder ball (321) provided on the columnar electrode. The columnar electrode comprises a main body (307) and a groove in the main body (307), and an opening of the groove is overlapped with the top surface of the columnar electrode. The solder ball (321) comprises a metal bump (320) arranged on the top of the columnar electrode and a filling part (319) filled in the groove. The solder ball and the columnar electrode form a structure similar to a bolt; thus the binding force between the solder ball and the columnar electrode is improved.