A method of forming a titanium nitride (TiN) diffusion barrier includes exposing a deposition surface to a first pulse of a titanium-containing precursor and to a first pulse of a nitrogen-rich plasma to form a first TiN layer with a first nitrogen concentration making a lower portion of the TiN diffusion barrier, the first nitrogen concentration of the first TiN layer is increased by the first pulse of the nitrogen-rich plasma reducing a reactivity of the lower portion of the TiN diffusion barrier to prevent fluorine diffusion. The first TiN layer is exposed to second pulses of the titanium-containing precursor and the nitrogen-rich plasma to form a second TiN layer with a second nitrogen concentration above the first TiN layer making an upper portion of the TiN diffusion barrier, the first pulse of the nitrogen-rich plasma has a substantially longer duration than the second pulse of the nitrogen-rich plasma.

A nitrogen plasma treatment is used on an adhesion layer of a contact plug. As a result of the nitrogen plasma treatment, nitrogen is incorporated into the adhesion layer. When a contact plug is deposited in the opening, an interlayer of a metal nitride is formed between the contact plug and the adhesion layer. A nitrogen plasma treatment is used on an opening in an insulating layer. As a result of the nitrogen plasma treatment, nitrogen is incorporated into the insulating layer at the opening. When a contact plug is deposited in the opening, an interlayer of a metal nitride is formed between the contact plug and the insulating layer.

A semiconductor structure includes at least one first semiconductor device located on a substrate, lower-level dielectric material layers embedding lower-level metal interconnect structures, at least one second semiconductor device and a dielectric material portion that overlie the lower-level dielectric material layers, at least one upper-level dielectric material layer, and an interconnection via structure vertically extending from the at least one upper-level dielectric material layer to a conductive structure that can be a node of the at least one first semiconductor device or one of lower-level metal interconnect structures. The interconnection via structure includes a transition metal layer and a fluorine-doped filler material portion in contact with the transition metal layer, composed primarily of a filler material selected from a silicide of the transition metal element or aluminum oxide, and including fluorine atoms.

The present disclosure provides a semiconductor device capable of improving element performance and reliability. The semiconductor device comprises a lower wiring structure, an upper interlayer insulating layer disposed on the lower wiring structure and including an upper wiring trench, the upper wiring trench exposing a portion of the lower wiring structure, and an upper wiring structure including an upper liner and an upper filling layer on the upper liner in the upper wiring trench, wherein the upper liner includes a sidewall portion extending along a sidewall of the upper wiring trench and a bottom portion extending along a bottom surface of the upper wiring trench, the sidewall portion of the upper liner includes cobalt (Co) and ruthenium (Ru), and the bottom portion of the upper liner is formed of cobalt (Co).

Semiconductor devices include a patterned dielectric layer overlaying a semiconductor substrate; a metal layer comprising copper disposed in the patterned dielectric layer; and a barrier layer formed at an interface between the dielectric layer and the metal layer, wherein the barrier layer is AlOxNy. The patterned dielectric may define a trench and via interconnect structure or first and second trenches for a capacitor structure. Also disclosed are processes for forming the semiconductor device, which includes subjecting the dielectric surfaces to a nitridization process to form a nitrogen enriched surface. Aluminum metal is then conformally deposited onto the nitrogen enriched surfaces to form AlOxNy at the aluminum metal/dielectric interface. The patterned substrate is then metallized with copper and annealed. Upon annealing, a copper aluminum alloy is formed at the copper metal/aluminum interface.

A semiconductor device including an insulating structure, and a conductive structure in the insulating structure may be provided. The conductive structure includes a barrier layer, an anti-migration layer on the barrier layer, a liner on the anti-migration layer, a conductive layer on the liner, and a capping layer covering a top surface of the barrier layer and a top surface of the anti-migration layer. The capping layer and the liner include Co. The anti-migration layer includes Mn.

A method of forming a semiconductor device includes forming an opening in a dielectric layer, and forming a barrier layer in the opening. A combined liner layer is formed over the barrier layer by first forming a first liner layer over the barrier layer, and forming a second liner layer over the first liner layer, such that the first liner layer and the second liner layer intermix. A conductive material layer is formed over the combined liner layer, and a thermal process is performed to reflow the conductive material layer.

An opening is formed through a dielectric material layer to physically expose a top surface of a conductive material portion in, or over, a substrate. A metallic nitride liner is formed on a sidewall of the opening and on the top surface of the conductive material portion. A metallic adhesion layer including an alloy of copper and at least one transition metal that is not copper is formed on an inner sidewall of the metallic nitride liner. A copper fill material portion may be formed on an inner sidewall of the metallic adhesion layer. The metallic adhesion layer is thermally stable, and remains free of holes during subsequent thermal processes, which may include reflow of the copper fill material portion. An additional copper fill material portion may be optionally deposited after a reflow process.

Embodiments are directed to a method of forming a semiconductor device and resulting structures having an air spacer between a gate and a contact by forming a gate on a substrate and over a channel region of a semiconductor fin. A contact is formed on a doped region of the substrate such that a space between the contact and the gate defines a trench. A first dielectric layer is formed over the gate and the contact such that the first dielectric layer partially fills the trench. A second dielectric layer is formed over the first dielectric layer such that an air spacer forms in the trench between the gate and the contact.

A method for fabricating a metallization layer of a semiconductor device, in which copper is used for an interconnect material and cobalt is used to encapsulate the copper, includes introducing a material that will form an alloy with cobalt and resist a degradation of an effect of the cobalt on encapsulating the copper.