A method for etching a metal containing feature is provided. Using a pattern mask, layers of material are etched to expose a portion of a metal containing feature. At least a portion of the exposed metal containing feature is etched, and is replaced by the growth of a filler dielectric. The etched portion of the metal containing feature and the filler dielectric reduce the unwanted conductivity between adjacent metal containing features.

In one example, an electroplating system comprises a first bath reservoir, a second bath reservoir, a clamp, a first anode in the first bath reservoir, a second anode in the second bath reservoir, and a direct current power supply. The first bath reservoir contains a first electrolyte solution that includes an alkaline copper-complexed solution. The second bath reservoir contains a second electrolyte solution that includes an acidic copper plating solution. The direct current power supply generates a first direct current between the clamp and the first anode to electroplate a first copper layer on the cobalt layer of the wafer submerged in the first electrolyte solution. The direct current power supply then generates a second direct current between the clamp and the second anode to electroplate a second copper layer on the first copper layer of the wafer submerged in the second electrolyte solution.

Stacked die modules for semiconductor device assemblies and methods of manufacturing the modules are disclosed. In some embodiments, the module includes a shingled stack of semiconductor dies, each die having an uncovered porch with bond pads. Further, a dielectric structure partially encapsulates the shingled stack of semiconductor dies. The dielectric structure includes openings corresponding to the bond pads. The module also includes conductive structures disposed on the dielectric structure, where each of the conductive structures extends over at least one porch of the semiconductor dies to connect to at least one bond pad through a corresponding opening. The semiconductor device assembly may include a controller die attached to a package substrate, the controller die carrying one or more stacked die modules, and bonding wires connecting terminals of the modules to package bond pads.

Disclosed herein are methods for etch barrier deposition that can include depositing a seed layer onto a substrate, depositing a metal layer onto the seed layer in a predetermined pattern, coating the metal layer with a barrier layer, directionally etching the barrier layer from a direction orthogonal to the substrate such that at least a portion of the barrier layer oriented parallel to the direction of the directional etching remains coated on the metal layer, and etching the portion of the seed layer to remove the seed layer from the substrate.

A via connection layer for an electronic package and method for fabricating a via connection layer are provided. The via connection layer includes asymmetric via(s) formed in the via connection layer. The asymmetric via include a first sidewall with a first slope angle in a first direction and a second sidewall, where the second sidewall includes a second slope angle in the first direction.

Methods and systems for cleaning and treating a surface of a substrate. An exemplary method includes providing a substrate comprising a gap comprising a metal oxide and a dielectric material within a reaction chamber, and using a thermal process to selectively remove the metal oxide. Exemplary methods can further include a step of depositing a metal-containing material within the gap to at least partially fill the gap and using a direct plasma and treating a surface of the metal-containing material to remove oxygen from the surface of the metal-containing material. Exemplary systems can perform the methods.

A method and apparatus for processing a substrate are described herein. The methods and apparatus described enable the raising and lowering of a shadow ring within a process chamber either simultaneously with or separately from a plurality of substrate lift pins. The shadow ring is raised and lowered using a shadow ring lift assembly and may be raised to a pre-determined height above the substrate during a radical treatment operation. The shadow ring lift assembly may also raise and lower the plurality of substrate lift pins to enable both the shadow ring and the substrate lift pins to be raised to a transfer position when the substrate is being transferred into or out of the process chamber.

Embodiments described herein relate generally to one or more methods for forming an interconnect structure, such as a dual damascene interconnect structure comprising a conductive line and a conductive via, and structures formed thereby. In some embodiments, an interconnect opening is formed through one or more dielectric layers over a semiconductor substrate. The interconnect opening has a via opening and a trench over the via opening. A conductive via is formed in the via opening. A nucleation enhancement treatment is performed on one or more exposed dielectric surfaces of the trench. A conductive line is formed in the trench on the one or more exposed dielectric surfaces of the trench and on the conductive via.

An interconnect structure of a semiconductor device includes a conductive via and a barrier layer lining an interface between a dielectric layer and the conductive via. The barrier layer is selectively deposited along sidewalls of a recess formed in a dielectric layer. The conductive via is formed by selectively electroplating electrically conductive material such as rhodium, iridium, or platinum in an opening of the recess, where the conductive via is grown upwards from an exposed metal surface at a bottom of the recess. The conductive via includes an electrically conductive material having a low electron mean free path, low electrical resistivity, and high melting point. The interconnect structure of the semiconductor device has reduced via resistance and improved resistance to electromigration and/or stress migration.

A metal interconnect structure is doped with zinc, indium, or gallium using top-down doping processes to improve diffusion barrier properties with minimal impact on line resistance. Dopant is introduced prior to metallization or after metallization. Dopant may be introduced by chemical vapor deposition on a liner layer at an elevated temperature prior to metallization, by chemical vapor deposition on a metal feature at an elevated temperature after metallization, or by electroless deposition on a copper feature after metallization. Application of elevated temperatures causes the metal interconnect structure to be doped and form a self-formed barrier layer or strengthen an existing diffusion barrier layer.