An aluminum or copper alloy sputtering chamber includes a front surface, a back surface opposite the front surface, and a sputter trap formed on at least a portion of the front surface A coating of titanium particles is formed on the sputter trap.

Deposition methods and apparatus for conditioning a process kit to increase process kit lifetime are described. A nitride film formed on a process kit is exposed to conditioning process comprising nitrogen and hydrogen radicals to condition the nitride film to decrease particulate contamination from the process kit.

Disclosed is a method of treating a substrate by using a substrate treating apparatus generating plasma in a treatment space by applying microwaves, the method including: a plasma treatment operation of treating a substrate with the plasma; a replacement operation in which the plasma treatment operation is performed a preset number of times and a component included in the substrate treating apparatus is replaced; and a backup operation of backing up the substrate treating apparatus after the replacement operation, in which the backup operation includes a bake purge operation for removing byproducts present in the component.

An apparatus for a semiconductor process includes an exhaust pipe coupled to a reaction chamber and a pump; a pressure control valve that is coupled to the exhaust pipe and configured to control a pressure value in the reaction chamber; a first pipe that is coupled to the exhaust pipe and etching gas source such that the first pipe is configured to provide an etching gas into the exhaust pipe; a second pipe that is coupled to the exhaust pipe and a radical generator such that the second pipe is configured to provide a radical into the exhaust pipe; and a third pipe that is coupled to the exhaust pipe and a diluted gas source such that the third pipe is configured to provide diluted gas into the exhaust pipe.

Apparatus for improved particle reduction are provided herein. In some embodiments, an apparatus may include a process kit shield comprising a one-piece metal body having an upper portion and a lower portion and having an opening disposed through the one-piece metal body, wherein the upper portion includes an opening-facing surface configured to be disposed about and spaced apart from a target of a physical vapor deposition chamber and wherein the opening-facing surface is configured to limit particle deposition on an upper surface of the upper portion of the one-piece metal body during sputtering of a target material from the target of the physical vapor deposition chamber.

A system and method for a waferless cleaning method for a capacitive coupled plasma system. The method includes forming a protective layer on a top surface of an electrostatic chuck, volatilizing etch byproducts deposited on one or more inner surfaces of the plasma process chamber, removing volatilized etch byproducts from the plasma process chamber and removing the protective layer from the top surface of the electrostatic chuck. A capacitive coupled plasma system including a waferless cleaning recipe is also described.

A precleaning chamber (100, 200, 300) and a plasma processing apparatus, comprising a cavity (20) and a dielectric window (21, 21′) disposed at the top of the cavity (20), a base (22 ) and a process assembly (24) surrounding the base (22) are disposed in the precleaning chamber (100, 200, 300), and the base (22), the process assembly (24 ) and the dielectric window (21, 21′) together form a process sub-cavity (211) above the base (22); and a space of the cavity (20) located below the base (22) is used as a loading/unloading sub-cavity (202), the precleaning chamber (100, 200, 300) further comprises a gas is device (32), the gas inlet device (32) comprises a gas inlet (323), and the gas inlet (323) is configured to directly transport a process gas into the process sub-cavity (211) from above the process assembly (24). The precleaning chamber (100, 200, 300) not only shortens the gas inlet path of the process gas, but also reach a desired plasma density under the conditions where a relatively small amount of process gas is introduced, thereby reducing the usage cost.

An apparatus of processing a target substrate is provided. The apparatus includes a processing chamber having a substantially cylindrical inner space, a mounting table disposed in the processing chamber and configured to mount thereon the target substrate, at least one supply line configured to supply a gas in a direction along an inner wall surface of a sidewall of the processing chamber to generate a swirl flow of the gas in the processing chamber, and a ventilator configured to exhaust the gas from the processing chamber. Further, in a direction intersecting an axis of the substantially cylindrical inner space, a flow velocity of the gas in a first region close to the inner wall surface is higher than a flow velocity of the gas in a second region where the mounting table is disposed.

Provided are an adhesion removal method capable of removing sulfur-containing adhesions that adhere onto the inner surface of a chamber or the inner surface of a pipe connected to the chamber without disassembly of the chamber and a film-forming method. Sulfur-containing adhesions adhering onto at least one of the inner surface of a chamber (10) and the inner surface of a discharge pipe (15) connected to the chamber (10) are removed by reaction with a cleaning gas containing a fluorine-containing compound gas.

A chamber cleaning method includes processing a wafer for a Cu-to-Cu bonding process using plasma in a chamber; and removing copper from the chamber. Removing copper includes forming copper oxide on an inner wall of the chamber by oxidizing copper in the chamber by a plasma treatment that uses a first gas, performing a first monitoring operation that monitors a copper contamination state in the chamber using an optical diagnostic method, removing the copper oxide by a plasma treatment that uses a second gas; and performing a second monitoring operation that monitors a copper contamination state in the chamber using the optical diagnostic method.