A semiconductor device includes a metal pattern filling a trench formed through at least a portion of an insulating interlayer on a substrate and including copper, and a wetting improvement layer pattern in the metal pattern including at least one of tantalum, tantalum nitride, titanium, titanium nitride, ruthenium, cobalt and manganese.

A method and system for coating the interior surfaces of microscale hole features fabricated into the substantially planar surface of a work piece. The method comprises providing a work piece with a barrier metal coating that is substantially continuous and uniform both along the planar surface of the work piece and the inner surfaces of the microscale hole features wherein said barrier metal coating is applied by a substantially surface reaction limited process. The workpiece is provided with a coating, on the planar surface of the work piece, of a thick metal layer anchored to the barrier metal coat and disposed to provide substantially uniform electrical conduction capability to the microscale features located throughout and across the workpiece. An electrical contact path is provided to the electrically conductive coating at the perimeter of the work piece. The workpiece is immersed in a chemical bath, causing said chemical bath to fully contact the interior surfaces of the microscale hole features, said chemical bath containing metal ions suitable for electrodeposition. An electric potential is applied at the perimeter of the work piece to cause electrodeposition of metal ions onto all surfaces of the work piece including the interior surfaces of the microscale hole features to a predetermined finish coating in one step.

One embodiment of the present invention is a method for depositing two or more PVD seed layers for electroplating metallic interconnects over a substrate, the substrate including a patterned insulating layer which includes at least one opening surrounded by a field, the at least one opening having top corners, sidewalls, and bottom, the field and the at least one opening being ready for depositing one or more seed layers, and the method includes: (a) depositing by a PVD technique, in a PVD chamber, a continuous PVD seed layer over the sidewalls and bottom of the at least one opening, using a first set of deposition parameters; and (b) depositing by a PVD technique, in a PVD chamber, another PVD seed layer over the substrate, using a second set of deposition parameters, wherein (i) the second set of deposition parameters includes at least one deposition parameter which is different from any of the parameters in the first set of deposition parameters, or the second set of deposition parameters includes at least one deposition parameter whose value is different in the two sets of deposition parameters, (ii) at least one of the PVD seed layers includes a material selected from a group consisting of Cu, Ag, or alloys including one or more of these metals, (iii) the PVD seed layers have no substantial overhangs sealing or pinching-off the top corners of the at least one opening, (iv) the combined thickness of the seed layers over the field is sufficient to enable uniform electroplating across the substrate, and (v) the combined seed layers inside the at least one opening leave sufficient room for electroplating inside the at least one opening.

A method for forming metallization in a workpiece includes electrochemically depositing a second metallization layer on the workpiece comprising a nonmetallic substrate having a dielectric layer disposed over a substrate and a continuous first metallization layer disposed on the dielectric layer and having at least one microfeature comprising a recessed structure, wherein the first metallization layer at least partially fills a feature on the workpiece, where the first metallization layer is a cobalt or nickel metal layer, and wherein the second metallization layer is a cobalt or nickel metal layer that is different from the metal of the first metallization layer, electrochemically depositing a copper cap layer after filling the feature, and annealing the workpiece to diffuse the metal of the second metallization layer into the metal of the first metallization layer.

In a method for forming a three-dimensional interconnection, a contact plug is formed within a through hole provided in a substrate and an upper wire formed on an upper side of the substrate and a lower wire formed on a lower side are electrically connected to one another by the contact plug. A coating film is formed on an upper surface of the substrate and inner surface of the through hole by applying a metal film-forming composition containing at least one salt of and a particle of a metal to the substrate provided with the through hole. A metal film is formed by heating the coating film, and plated by filling up the through hole by depositing a conductor on the metal film by a plating process using the metal film as a seed layer. An excess conductor deposited in the plating is removed by a chemical mechanical polishing process.

An integrated circuit device includes a capacitor structure, wherein the capacitor structure includes: a bottom electrode over a substrate; a supporter on a sidewall of the bottom electrode; a dielectric layer on the bottom electrode and the supporter; and a top electrode on the dielectric layer and covering the bottom electrode. The bottom electrode comprises: a base electrode layer over the substrate and extending in a first direction that is perpendicular to a top surface of the substrate, and a conductive capping layer including niobium nitride that is between a sidewall of the base electrode layer and the dielectric layer, and also between a top surface of the base electrode layer and the dielectric layer.