Organometallic precursors and methods of depositing high purity metal films are discussed. Some embodiments utilize a method comprising exposing a substrate surface to an organometallic precursor comprising one or more of molybdenum (Mo), tungsten (W), osmium (Os), technetium (Tc), manganese (Mn), rhenium (Re) or ruthenium (Ru), and an iodine-containing reactant comprising a species having a formula RI.sub.x, where R is one or more of a C.sub.1-C.sub.10 alkyl, C.sub.3-C.sub.10 cycloalkyl, C.sub.2-C.sub.10 alkenyl, or C.sub.2-C.sub.10 alkynyl group, I is an iodine group and x is in a range of 1 to 4 to form a carbon-less iodine-containing metal film. Some embodiments advantageously provide methods of forming metal films having low carbon content (e.g., having greater than or equal to 95% metal species on an atomic basis), without using an oxidizing agent or a reductant.

Process for manufacturing a nuclear component comprising i) a support containing a substrate based on a metal (1), the substrate (1) being coated or not coated with an interposed layer (3) positioned between the substrate (1) and at least one protective layer (2) and ii) the protective layer (2) composed of a protective material comprising chromium; the process comprising a step a) of vaporizing a mother solution followed by a step b) of depositing the protective layer (2) onto the support via a process of chemical vapor deposition of an organometallic compound by direct liquid injection (DLI-MOCVD).

Nuclear component comprising i) a support containing a substrate based on a metal, the substrate (1) being coated or not coated with an interposed layer (3) positioned between the substrate (1) and at least one protective layer (2) and ii) the protective layer (2) composed of a protective material comprising chromium. The composite nuclear component manufactured by the process of the invention has improved resistance to oxidation, hydriding and/or migration of undesired material.

The invention also relates to the use of the nuclear component for combating oxidation and/or hydriding.

Process for manufacturing a nuclear component comprising i) a support containing a substrate based on a metal (1), the substrate (1) being coated or not coated with an interposed layer (3) positioned between the substrate (1) and at least one protective layer (2) and ii) the protective layer (2) composed of a protective material comprising chromium; the process comprising a step a) of vaporizing a mother solution followed by a step b) of depositing the protective layer (2) onto the support via a process of chemical vapor deposition of an organometallic compound by direct liquid injection (DLI-MOCVD).

Nuclear component comprising i) a support containing a substrate based on a metal, the substrate (1) being coated or not coated with an interposed layer (3) positioned between the substrate (1) and at least one protective layer (2) and ii) the protective layer (2) composed of a protective material comprising chromium. The composite nuclear component manufactured by the process of the invention has improved resistance to oxidation, hydriding and/or migration of undesired material.

The invention also relates to the use of the nuclear component for combating oxidation and/or hydriding.

A method can include vapor depositing a corrosion resistant coating to internal and external surfaces of a metallic air data probe. For example, vapor depositing can include using atomic layer deposition (ALD). The method can include placing the metallic air data probe in a vacuum chamber and evacuating the vacuum chamber before using vapor deposition. The corrosion resistant coating can be or include a ceramic coating. In certain embodiments, vapor depositing can include applying a first precursor, then applying a second precursor to the first precursor to form the ceramic coating.

There is provided a stress reducing method comprising: preparing a film forming apparatus configured to form a tungsten film on a substrate in a chamber by supplying a tungsten raw material gas and a reducing gas into the chamber; and making at least a part of a tungsten film deposited on an in-chamber component into a chlorine-containing tungsten film whose film stress is reduced by adjusting a chlorine concentration, when performing precoating in the chamber and/or when forming the tungsten film on the substrate, using the tungsten raw material gas and the reducing gas.

There is provided a stress reducing method comprising: preparing a film forming apparatus configured to form a tungsten film on a substrate in a chamber by supplying a tungsten raw material gas and a reducing gas into the chamber; and making at least a part of a tungsten film deposited on an in-chamber component into a chlorine-containing tungsten film whose film stress is reduced by adjusting a chlorine concentration, when performing precoating in the chamber and/or when forming the tungsten film on the substrate, using the tungsten raw material gas and the reducing gas.

A method of depositing nitride films is disclosed. Some embodiments of the disclosure provide a PEALD process for depositing nitride films which utilizes separate reaction and nitridation plasmas. In some embodiments, the nitride films have improved growth per cycle (GPC) relative to films deposited by thermal processes or plasma processes with only a single plasma exposure. In some embodiments, the nitride films have improved film quality relative to films deposited by thermal processes or plasma processes with only a single plasma exposure.

A method of depositing nitride films is disclosed. Some embodiments of the disclosure provide a PEALD process for depositing nitride films which utilizes separate reaction and nitridation plasmas. In some embodiments, the nitride films have improved growth per cycle (GPC) relative to films deposited by thermal processes or plasma processes with only a single plasma exposure. In some embodiments, the nitride films have improved film quality relative to films deposited by thermal processes or plasma processes with only a single plasma exposure.

Described herein are compositions and methods for forming silicon and oxygen containing films. In one aspect, the film is deposited from at least one precursor, wherein the at least one precursor selected from the group consisting of Formula C: ##STR00001##
as defined herein.

A patterned backside stress compensation film having different stress in different sectors is formed on a backside of a substrate to reduce combination warpage of the substrate. The film can be formed by employing a radio frequency electrode assembly including plurality of conductive plates that are biased with different RF power and cause local variations in the plasma employed to deposit the backside film. Alternatively, the film may be deposited with uniform stress, and some of its sectors are irradiated with ultraviolet radiation to change the stress of these irradiated sectors. Yet alternatively, multiple backside deposition processes may be sequentially employed to deposit different backside films to provide a composite backside film having different stresses in different sectors.