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: In some embodiments, a showerhead assembly includes a heated showerhead having a heater plate and a gas distribution plate coupled together; an ion filter spaced from the heated showerhead; a spacer ring in contact between the heated showerhead and the ion filter; a remote plasma region between the heated showerhead and the ion filter; an upper isolator spaced from the spacer ring and supported on the ion filter; a sealing ring fastened to the heated showerhead sealing against the upper isolator and pushing the upper isolator against the ion filter; a gap between a bottom of the gas distribution plate and a top of the ion filter, the gap being in fluid communication with the remote plasma region; a first passage extending through the heater plate; and a second passage in communication with the first passage and extending through the gas distribution plate, the second passage extending to the gap.

Abstract: Methods and apparatus for processing a substrate are provided herein. For example, a method for processing a substrate comprises forming a plasma reaction between titanium tetrachloride (TlCl4), hydrogen (H2), and argon (Ar) in a region between a lid heater and a showerhead of a process chamber or the showerhead and a substrate while providing RF power at a pulse frequency of about 5 kHz to about 100 kHz and at a duty cycle of about 10% to about 20% and flowing reaction products into the process chamber to selectively form a titanium material layer upon a silicon surface of the substrate.

Abstract: A method and apparatus for nitride capping of titanium materials via chemical vapor deposition techniques is provided. The method includes forming a titanium nitride layer upon a titanium material layer formed on a substrate. The titanium nitride layer is formed by exposing the titanium material layer to a hydrogen-rich nitrogen-containing plasma followed by exposing the titanium material layer to a nitrogen-rich nitrogen-containing plasma. The titanium nitride layer is then exposed to an argon plasma followed by exposing the titanium nitride layer to a halide soak process.

Abstract: A method and apparatus for nitride capping of titanium materials via chemical vapor deposition techniques is provided. The method includes forming a titanium nitride layer upon a titanium material layer formed on a substrate. The titanium nitride layer is formed by exposing the titanium material layer to a hydrogen-rich nitrogen-containing plasma followed by exposing the titanium material layer to a nitrogen-rich nitrogen-containing plasma. The titanium nitride layer is then exposed to an argon plasma followed by exposing the titanium nitride layer to a halide soak process.