Abstract: Methods for reducing contact resistance include performing a selective titanium silicide (TiSi) deposition process on a middle of the line (MOL) contact structure that includes a cavity in a substrate of dielectric material. The contact structure also includes a silicon-based connection portion at a bottom of the cavity. The selective TiSi deposition process is selective to silicon-based material over dielectric material. The methods also include performing a selective deposition process of a metal material on the MOL contact structure. The selective deposition process is selective to TiSi material over dielectric material and forms a silicide capping layer on the silicon-based connection portion. The methods further include performing a seed layer deposition process of the metal material on the contact structure.

Abstract: A method for forming a metal nitride layer on a substrate includes exposing a substrate having features formed therein to a first deposition gas mixture including metal source material in a processing chamber to deposit metal source material in the features, supplying a first purge gas mixture into the processing chamber to remove excess metal source material and reaction byproducts from the processing chamber, exposing the substrate to a second deposition gas mixture including a nitride source compound in the processing chamber to form no more than one monolayer of metal nitride, supplying a second purge gas mixture into the processing chamber to remove excess nitride source compound and reaction byproducts from the processing chamber, and exposing the substrate to plasma using a microwave plasma source.

Abstract: A method for forming a metal nitride layer on a substrate includes exposing a substrate having features formed therein to a first deposition gas mixture including metal source material in a processing chamber to deposit metal source material in the features, supplying a first purge gas mixture into the processing chamber to remove excess metal source material and reaction byproducts from the processing chamber, exposing the substrate to a second deposition gas mixture including a nitride source compound in the processing chamber to form no more than one monolayer of metal nitride, supplying a second purge gas mixture into the processing chamber to remove excess nitride source compound and reaction byproducts from the processing chamber, and exposing the substrate to plasma using a microwave plasma source.

Abstract: Methods for filling a substrate feature with a seamless metal gate fill are described. Methods comprise sequentially depositing a film on a substrate surface having at least one feature thereon. The at least one feature extends a feature depth from the substrate surface to a bottom surface and has a width defined by a first sidewall and a second sidewall. The film is treated with an oxidizing plasma. Then the film is etched to remove the oxidized film. A second film is deposited to fill the feature, where the second film substantially free of seams and voids.

Abstract: A sacrificial sealing layer is formed on a high-K metal gate (HKMG) stack to suppress oxidants, e.g., oxygen and water, from impacting the metal gate stack, thus preserving the device EOT. The method integrated processes that include forming an interfacial layer on the substrate; forming a high-K metal oxide layer on the interfacial layer, the high-K metal oxide layer comprising a dipole region adjacent to the interfacial layer, the dipole region; depositing a capping layer on the high-K metal oxide layer; and forming a sacrificial sealing layer on the capping layer. The dipole region is formed by driving a dopant species, e.g., zinc (Zn), vanadium (V), tungsten (W), molybdenum (Mo), ruthenium (Ru), titanium (Ti), tantalum (Ta), zirconium (Zr), aluminum (Al), niobium (Nb), or mixtures thereof, of a dipole film into the high-K metal oxide layer to form a dipole region.

Abstract: A method for forming a metal nitride layer on a substrate includes exposing a substrate having features formed therein to a first deposition gas mixture including metal source material in a processing chamber to deposit metal source material in the features, supplying a first purge gas mixture into the processing chamber to remove excess metal source material and reaction byproducts from the processing chamber, exposing the substrate to a second deposition gas mixture including a nitride source compound in the processing chamber to form no more than one monolayer of metal nitride, supplying a second purge gas mixture into the processing chamber to remove excess nitride source compound and reaction byproducts from the processing chamber, and exposing the substrate to plasma using a microwave plasma source.

Abstract: In-situ methods for depositing a metal film without the use of a barrier layer are disclosed. Some embodiments comprise forming an amorphous nucleation layer comprising one or more of silicon or boron and forming a metal layer on the nucleation layer. These processes are performed without an air break between processes.

Abstract: In-situ methods for depositing a metal film without the use of a barrier layer are disclosed. Some embodiments comprise forming an amorphous nucleation layer comprising one or more of silicon or boron and forming a metal layer on the nucleation layer. These processes are performed without an air break between processes.