US20070141274A1 - Barrier metal film production apparatus, barrier metal film production method, metal film production method, and metal film production apparatus - Google Patents

Abstract

A Cl₂gas plasma is generated at a site within a chamber between a substrate and a metal member. The metal member is etched with the Cl₂gas plasma to form a precursor. A nitrogen gas is excited in a manner isolated from the chamber accommodating the substrate. A metal nitride is formed upon reaction between excited nitrogen and the precursor, and formed as a film on the substrate. After film formation of the metal nitride, a metal component of the precursor is formed as a film on the metal nitride on the substrate. In this manner, a barrier metal film with excellent burial properties and a very small thickness is produced at a high speed, with diffusion of metal being suppressed and adhesion to the metal being improved.

Description

• The entire disclosures of Japanese Patent Application No. 2002-44296 filed on Feb. 21, 2002, Japanese Patent Application No. 2002-44289 filed on Feb. 21, 2002, Japanese Patent Application No. 2002-027738 filed on Feb. 5, 2002, and Japanese Patent Application No. 2001-348325 filed on Nov. 14, 2001, each including specification, claims, drawings and summary, are incorporated herein by reference in their entirety.
BACKGROUND OF THE INVENTION
• 1. Field of the Invention
• This invention relates to a production apparatus and a production method for a barrier metal film to be formed on the surface of a substrate for eliminating the diffusion of a metal into the substrate and retaining the adhesion of the metal, when a metal film is formed on the surface of the substrate.
• The present invention also relates to a metal film production method and a metal film production apparatus which can form a film of a metal, with the diffusion of the metal being eliminated and the adhesion of the metal being retained, by treating the surface of a barrier metal film produced on a substrate.
• 2. Description of Related Art
• Semiconductors with electrical wiring have increasingly used copper as a material for the wiring in order to increase the speed of switching, decrease transmission loss, and achieve a high density. In applying the copper wiring, it has been common practice to perform the vapor phase growth method or plating on a substrate having a depression for wiring on its surface, thereby forming a copper film on the surface including the depression.
• In forming the copper film on the surface of the substrate, a barrier metal film (for example, a nitride of tantalum, tungsten, titanium or silicon) is prepared beforehand on the surface of the substrate in order to eliminate the diffusion of copper into the substrate, and retain the adhesion of copper. When plating is employed, a copper shielding layer is formed on the barrier metal film by physical or chemical vapor deposition, and used also as an electrode. The barrier metal film has been formed by physical vapor deposition such as sputtering.
• The depression for wiring, formed on the surface of the substrate, tends to be decreased in size, and a demand is expressed for a further reduction in the thickness of the barrier metal film. However, the barrier metal film has been produced by use of sputtering, and its directionality is not uniform. With a tiny depression on the surface of the substrate, therefore, the film is formed at the entrance of the depression before being formed in the interior of the depression, resulting in insufficient burial of the depression. Also, the substrate has been badly damaged.
• Additionally, the barrier metal film is prepared for the purposes of preventing the diffusion of copper into the substrate and retaining the adhesion of copper. Hence, a nitride of tantalum, tungsten or titanium is formed as a first layer for prevention of copper diffusion, and an active metal, such as tantalum, tungsten or titanium, is formed as a second layer for retention of adhesion to copper. However, the barrier metal film is so thin that it poses difficulty at the present time in performing both functions, the prevention of copper diffusion into the substrate and the retention of copper adhesion. A demand is growing for the advent of a barrier metal film which accomplishes these two functions.
• In particular, the wiring depression formed on the surface of the substrate is showing a tendency toward compactness, and further thinning of the barrier metal film is demanded. However, the necessary minimum film thickness has increased, if the barrier metal film is constructed in a two-layer structure by forming a nitride of tantalum, tungsten or titanium as a first layer for prevention of copper diffusion, and forming an active metal, such as tantalum, tungsten or titanium, as a second layer for retention of adhesion to copper.
SUMMARY OF THE INVENTION
• The present invention has been accomplished in light of the circumstances described above. An object of the invention is to provide a barrier metal film production apparatus and a barrier metal film production method which can form a barrier metal film with excellent burial properties and a very small thickness at a high speed. Another object of the invention is to provide a barrier metal film production apparatus and a barrier metal film production method which can form a barrier metal film with excellent adhesion to a metal formed as a film on the surface of the substrate. Still another object of the invention is to provide a metal film production method and a metal film production apparatus capable of forming a barrier metal film which, although very thin, prevents diffusion of a metal and retains adhesion to the metal.
• According to the present invention, there is provided a barrier metal film production apparatus, comprising:
• a chamber accommodating a substrate;
• a metallic etched member provided in the chamber at a position opposed to the substrate;
• source gas supply means for supplying a source gas containing a halogen to an interior of the chamber between the substrate and the etched member;
• plasma generation means which converts an atmosphere within the chamber into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas;
• excitation means for exciting a nitrogen-containing gas in a manner isolated from the chamber;
• formation means for forming a metal nitride upon reaction between nitrogen excited by the excitation means and the precursor; and
• control means which makes a temperature of the substrate lower than a temperature of the formation means to form the metal nitride as a film on the substrate.
• Thus, a barrier metal film comprising a film of a metal nitride and suppressing diffusion can be prepared by forming a metal with the use of a plasma. The barrier metal film can be formed uniformly to a small thickness. Consequently, the barrier metal film can be formed highly accurately at a high speed with excellent burial properties in a very small thickness even to the interior of a tiny depression, for example several hundred nanometers wide, which has been provided in the substrate.
• According to the present invention, there is also provided a barrier metal film production apparatus, comprising:
• a chamber accommodating a substrate;
• a metallic etched member provided in the chamber at a position opposed to the substrate;
• source gas supply means for supplying a source gas containing a halogen to an interior of the chamber between the substrate and the etched member;
• plasma generation means which converts an atmosphere within the chamber into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas;
• excitation means for exciting a nitrogen-containing gas in a manner isolated from the chamber;
• formation means for forming a metal nitride upon reaction between nitrogen excited by the excitation means and the precursor; and
• control means which makes a temperature of the substrate lower than a temperature of the formation means to form the metal nitride as a film on the substrate, and after film formation of the metal nitride, stops supply of the nitrogen-containing gas, and makes the temperature of the substrate lower than a temperature of the etched member to form the metal component of the precursor as a film on the metal nitride on the substrate.
• Thus, a barrier metal film comprising a film of a metal nitride and a metal film and with diffusion suppressed and adhesion improved can be prepared by forming a metal by plasmas. The barrier metal film can be formed uniformly to a small thickness. Consequently, the barrier metal film can be formed highly accurately at a high speed with excellent burial properties in a very small thickness even to the interior of a tiny depression, for example several hundred nanometers wide, which has been provided in the substrate.
• According to the present invention, there is also provided a barrier metal film production apparatus, comprising:
• a chamber accommodating a substrate;
• a metallic etched member provided in the chamber at a position opposed to the substrate;
• source gas supply means for supplying a source gas containing a halogen to an interior of the chamber between the substrate and the etched member;
• nitrogen-containing gas supply means for supplying a nitrogen-containing gas to an interior of the chamber between the substrate and the etched member;
• plasma generation means which converts an atmosphere within the chamber into a plasma to generate a source gas plasma and a nitrogen-containing gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas, and that a metal nitride is formed upon reaction between nitrogen and the precursor; and
• control means which makes a temperature of the substrate lower than a temperature of the etched member to form the metal nitride as a film on the substrate.
• Thus, a barrier metal film comprising a film of a metal nitride and a metal film and with diffusion suppressed can be prepared by forming a metal by plasmas. The barrier metal film can be formed uniformly to a small thickness. Also, the supply lines for gases can be simplified, and the number of plasma sources can be decreased, so that the product cost can be reduced. Consequently, the barrier metal film can be formed highly accurately at a high speed and at a low cost with excellent burial properties in a very small thickness even to the interior of a tiny depression, for example several hundred nanometers wide, which has been provided in the substrate.
• According to the present invention, there is also provided a barrier metal film production apparatus, comprising:
• a chamber accommodating a substrate;
• a metallic etched member provided in the chamber at a position opposed to the substrate;
• source gas supply means for supplying a source gas containing a halogen to an interior of the chamber between the substrate and the etched member;
• nitrogen-containing gas supply means for supplying a nitrogen-containing gas to an interior of the chamber between the substrate and the etched member;
• plasma generation means which converts an atmosphere within the chamber into a plasma to generate a source gas plasma and a nitrogen-containing gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas, and that a metal nitride is formed upon reaction between nitrogen and the precursor; and
• control means which makes a temperature of the substrate lower than a temperature of the etched member to form the metal nitride as a film on the substrate, then stops supply of the nitrogen-containing gas, and makes the temperature of the substrate lower than the temperature of the etched member to form the metal component of the precursor as a film on the metal nitride on the substrate.
• Thus, a barrier metal film comprising a film of a metal nitride and a metal film and with diffusion suppressed and adhesion improved can be prepared by forming a metal by plasmas. The barrier metal film can be formed uniformly to a small thickness. Also, the supply lines for gases can be simplified, and the number of plasma sources can be decreased, so that the product cost can be reduced. Consequently, the barrier metal film can be formed highly accurately at a high speed and at a low cost with excellent burial properties in a very small thickness even to the interior of a tiny depression, for example several hundred nanometers wide, which has been provided in the substrate.
• According to the present invention, there is also provided a barrier metal film production method comprising:
• supplying a source gas containing a halogen to an interior of a chamber between a substrate and a metallic etched member;
• converting an atmosphere within the chamber into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas;
• exciting a nitrogen-containing gas in a manner isolated from the chamber accommodating the substrate;
• forming a metal nitride upon reaction between excited nitrogen and the precursor; and
• making a temperature of the substrate lower than a temperature of means for formation of the metal nitride to form the metal nitride as a film on the substrate.
• Thus, a barrier metal film comprising a film of a metal nitride and suppressing diffusion can be prepared by forming a metal by plasma. The barrier metal film can be formed uniformly to a small thickness. Consequently, the barrier metal film can be formed highly accurately at a high speed with excellent burial properties in a very small thickness even to the interior of a tiny depression, for example several hundred nanometers wide, which has been provided in the substrate.
• According to the present invention, there is also provided a barrier metal film production method comprising:
• supplying a source gas containing a halogen to an interior of a chamber between a substrate and a metallic etched member;
• converting an atmosphere within the chamber into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas;
• exciting a nitrogen-containing gas in a manner isolated from the chamber accommodating the substrate;
• forming a metal nitride upon reaction between excited nitrogen and the precursor;
• making a temperature of the substrate lower than a temperature of means for formation of the metal nitride to form the metal nitride as a film on the substrate; and
• after film formation of the metal nitride, stopping supply of the nitrogen-containing gas, and making the temperature of the substrate lower than a temperature of the etched member to form the metal component of the precursor as a film on the metal nitride on the substrate.
• Thus, a barrier metal film comprising a film of a metal nitride and a metal film and with diffusion suppressed and adhesion improved can be prepared by forming a metal by plasmas. The barrier metal film can be formed uniformly to a small thickness. Consequently, the barrier metal film can be formed highly accurately at a high speed with excellent burial properties in a very small thickness even to the interior of a tiny depression, for example several hundred nanometers wide, which has been provided in the substrate.
• According to the present invention, there is also provided a barrier metal film production method comprising:
• supplying a source gas containing a halogen and a nitrogen-containing gas to an interior of a chamber between a substrate and a metallic etched member;
• converting an atmosphere within the chamber into a plasma to generate a source gas plasma and a nitrogen-containing gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas, and that a metal nitride is formed upon reaction between nitrogen and the precursor; and
• making a temperature of the substrate lower than a temperature of the etched member to form the metal nitride as a film on the substrate.
• Thus, a barrier metal film comprising a film of a metal nitride and with diffusion suppressed can be prepared by forming a metal by plasmas. The barrier metal film can be formed uniformly to a small thickness. Also, the supply line for gases can be simplified, and the number of plasma sources can be decreased, so that the product cost can be reduced. Consequently, the barrier metal film can be formed highly accurately at a high speed and at a low cost with excellent burial properties in a very small thickness even to the interior of a tiny depression, for example several hundred nanometers wide, which has been provided in the substrate.
• According to the present invention, there is also provided a barrier metal film production method comprising:
• supplying a source gas containing a halogen and a nitrogen-containing gas to an interior of a chamber between a substrate and a metallic etched member;
• converting an atmosphere within the chamber into a plasma to generate a source gas plasma and a nitrogen-containing gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas, and that a metal nitride is formed upon reaction between nitrogen and the precursor;
• making a temperature of the substrate lower than a temperature of the etched member to form the metal nitride as a film on the substrate; and
• after film formation of the metal nitride, stopping supply of the nitrogen-containing gas, and making the temperature of the substrate lower than the temperature of the etched member to form the metal component of the precursor as a film on the metal nitride on the substrate.
• Thus, a barrier metal film comprising a film of a metal nitride and a metal film and with diffusion suppressed and adhesion improved can be prepared by forming a metal by plasmas. The barrier metal film can be formed uniformly to a small thickness. Also, the supply line for gases can be simplified, and the number of plasma sources can be decreased, so that the product cost can be reduced. Consequently, the barrier metal film can be formed highly accurately at a high speed and at a low cost with excellent burial properties in a very small thickness even to the interior of a tiny depression, for example several hundred nanometers wide, which has been provided in the substrate.
• According to the present invention, there is also provided a barrier metal film production apparatus, comprising:
• a chamber accommodating a substrate;
• a metallic etched member provided in the chamber at a position opposed to the substrate;
• source gas supply means for supplying a source gas containing a halogen into the chamber;
• nitrogen-containing gas supply means for supplying a gas containing nitrogen into the chamber;
• plasma generation means which converts an atmosphere within the chamber into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas, and which converts the atmosphere within the chamber into a plasma to generate a nitrogen-containing gas plasma so that a metal nitride is formed upon reaction between nitrogen and the precursor;
• control means which makes a temperature of the substrate lower than a temperature of the plasma generation means to form the metal nitride as a barrier metal film on a surface of the substrate;
• diluent gas supply means for supplying a diluent gas to a site above the surface of the substrate; and
• surface treatment plasma generation means for performing a surface treatment which converts the atmosphere within the chamber into a plasma to generate a diluent gas plasma so that nitrogen atoms in a superficial layer of the barrier metal film are removed by the diluent gas plasma to decrease a nitrogen content of the superficial layer relative to an interior of a matrix of the barrier metal film.
• Thus, a barrier metal film comprising a metal nitride layer and a metal layer can be prepared without the increase of the film thickness. Consequently, a barrier metal film production apparatus can be achieved which is capable of forming a barrier metal film at a high speed with excellent burial properties in a very small thickness, and also forming a barrier metal film with excellent adhesion to a metal formed as a film on the surface of the barrier metal film.
• The barrier metal film production apparatus may further comprise oxygen gas supply means for supplying an oxygen gas into the chamber immediately before formation of the most superficial layer of the barrier metal film is completed; and oxygen plasma generation means which converts the atmosphere within the chamber into a plasma to generate an oxygen gas plasma so that an oxide layer is formed on the most superficial layer of the barrier metal film.
• Thus, because of an oxide layer, if a metal is deposited on the surface of the barrier metal film, wettability by the metal can be rendered satisfactory, thus increasing adhesion.
• According to the present invention, there is also provided a barrier metal film production apparatus, comprising:
• a chamber accommodating a substrate;
• a metallic etched member provided in the chamber at a position opposed to the substrate;
• source gas supply means for supplying a source gas containing a halogen into the chamber;
• nitrogen-containing gas supply means for supplying a gas containing nitrogen into the chamber;
• plasma generation means which converts an atmosphere within the chamber into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas, and which converts the atmosphere within the chamber into a plasma to generate a nitrogen-containing gas plasma so that a metal nitride is formed upon reaction between nitrogen and the precursor;
• control means which makes a temperature of the substrate lower than a temperature of the plasma generation means to form the metal nitride as a barrier metal film on a surface of the substrate;
• oxygen gas supply means for supplying an oxygen gas to a site above the surface of the substrate; and
• oxygen plasma generation means for performing a surface treatment which converts the atmosphere within the chamber into a plasma to generate an oxygen gas plasma so that nitrogen atoms in a superficial layer of the barrier metal film are removed by the oxygen gas plasma to decrease a nitrogen content of the superficial layer relative to an interior of a matrix of the barrier metal film, and at the same time, forming an oxide layer on the most superficial layer of the barrier metal film.
• Thus, a barrier metal film comprising a metal nitride layer and a metal layer can be prepared with a minimum nozzle construction without the increase of the film thickness, and an oxide layer gives satisfactory wettability by a metal deposited on the surface of the barrier metal film. Consequently, a barrier metal film production apparatus can be achieved which is capable of forming a barrier metal film at a high speed with excellent burial properties in a very small thickness, and also forming a barrier metal film with excellent adhesion to a metal formed as a film on the surface of the barrier metal film.
• According to the present invention, there is also provided a barrier metal film production apparatus, comprising:
• a chamber accommodating a substrate;
• a metallic etched member provided in the chamber at a position opposed to the substrate;
• source gas supply means for supplying a source gas containing a halogen into the chamber;
• nitrogen-containing gas supply means for supplying a gas containing nitrogen into the chamber;
• plasma generation means which converts an atmosphere within the chamber into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas, and which converts the atmosphere within the chamber into a plasma to generate a nitrogen-containing gas plasma so that a metal nitride is formed upon reaction between nitrogen and the precursor;
• control means which makes a temperature of the substrate lower than a temperature of the plasma generation means to form the metal nitride as a film, for use as a barrier metal film, on a surface of the substrate;
• oxygen gas supply means for supplying an oxygen gas into the chamber immediately before formation of the most superficial layer of the barrier metal film is completed; and
• oxygen plasma generation means which converts the atmosphere within the chamber into a plasma to generate an oxygen gas plasma so that an oxide layer is formed on the most superficial layer of the barrier metal film.
• Thus, a barrier metal film comprising a metal nitride layer can be prepared without the increase of the film thickness, and an oxide layer gives satisfactory wettability by a metal deposited on the surface of the barrier metal film. Consequently, a barrier metal film production apparatus can be achieved which is capable of forming a barrier metal film at a high speed with excellent burial properties in a very small thickness, and also forming a barrier metal film with excellent adhesion to a metal formed as a film on the surface of the barrier metal film.
• According to the present invention, there is also provided a barrier metal film production apparatus, comprising:
• a chamber accommodating a substrate;
• a metallic etched member provided in the chamber at a position opposed to the substrate;
• source gas supply means for supplying a source gas containing a halogen into the chamber;
• nitrogen-containing gas supply means for supplying a gas containing nitrogen into the chamber;
• plasma generation means which converts an atmosphere within the chamber into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas, and which converts the atmosphere within the chamber into a plasma to generate a nitrogen-containing gas plasma so that a metal nitride is formed upon reaction between nitrogen and the precursor;
• control means which makes a temperature of the substrate lower than a temperature of the plasma generation means to form the metal nitride as a film on a surface of the substrate, then makes the temperature of the substrate lower than the temperature of the plasma generation means and stops supply of the gas containing nitrogen from the nitrogen-containing gas supply means, thereby forming the metal component of the precursor as a film on the metal nitride for use as a barrier metal film;
• oxygen gas supply means for supplying an oxygen gas into the chamber immediately before formation of the most superficial layer of the barrier metal film is completed; and
• oxygen plasma generation means which converts the atmosphere within the chamber into a plasma to generate an oxygen gas plasma so that an oxide layer is formed on the most superficial layer of the barrier metal film.
• Thus, a barrier metal film comprising a metal nitride layer and a metal layer can be prepared without the increase of the film thickness, and an oxide layer gives satisfactory wettability by a metal deposited on the surface of the barrier metal film. Consequently, a barrier metal film production apparatus can be achieved which is capable of forming a barrier metal film at a high speed with excellent burial properties, and also forming a barrier metal film with excellent adhesion to a metal formed as a film on the surface of the barrier metal film.
• According to the present invention, there is also provided a barrier metal film production apparatus, comprising:
• a chamber accommodating a substrate;
• a metallic etched member provided in the chamber at a position opposed to the substrate;
• source gas supply means for supplying a source gas containing a halogen into the chamber;
• plasma generation means which converts an atmosphere within the chamber into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas;
• excitation means for exciting a gas containing nitrogen in a manner isolated from the chamber;
• formation means for forming a metal nitride upon reaction between nitrogen excited by the excitation means and the precursor;
• control means which makes a temperature of the substrate lower than a temperature of the formation means to form the metal nitride as a film on the substrate for use as a barrier metal film;
• oxygen gas supply means for supplying an oxygen gas into the chamber immediately before formation of the most superficial layer of the barrier metal film is completed; and
• oxygen plasma generation means which converts the atmosphere within the chamber into a plasma to generate an oxygen gas plasma so that an oxide layer is formed on the most superficial layer of the barrier metal film.
• Thus, a barrier metal film comprising a metal nitride layer can be prepared without the increase of the film thickness, an oxide layer gives satisfactory wettability by a metal deposited on the surface of the barrier metal film, and the substrate can be free from exposure to a nitrogen-containing gas plasma. Consequently, a barrier metal film production apparatus can be achieved which is capable of forming a barrier metal film at a high speed with excellent burial properties in a very small thickness without exerting the influence of the nitrogen-containing gas plasma upon the substrate, and also forming a barrier metal film with excellent adhesion to a metal formed as a film on the surface of the barrier metal film.
• According to the present invention, there is also provided a barrier metal film production apparatus, comprising:
• a chamber accommodating a substrate;
• a metallic etched member provided in the chamber at a position opposed to the substrate;
• source gas supply means for supplying a source gas containing a halogen into the chamber;
• plasma generation means which converts an atmosphere within the chamber into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas;
• excitation means for exciting a gas containing nitrogen in a manner isolated from the chamber;
• formation means for forming a metal nitride upon reaction between nitrogen excited by the excitation means and the precursor;
• control means which makes a temperature of the substrate lower than a temperature of the formation means to form the metal nitride as a film on the substrate, and after film formation of the metal nitride, stops supply of the nitrogen-containing gas and makes the temperature of the substrate lower than a temperature of the etched member, thereby forming the metal component of the precursor as a film on the metal nitride on the substrate for use as a barrier metal film;
• oxygen gas supply means for supplying an oxygen gas into the chamber immediately before formation of the most superficial layer of the barrier metal film is completed; and
• oxygen plasma generation means which converts the atmosphere within the chamber into a plasma to generate an oxygen gas plasma so that an oxide layer is formed on the most superficial layer of the barrier metal film.
• Thus, a barrier metal film comprising a metal nitride layer can be prepared without the increase of the film thickness, an oxide layer gives satisfactory wettability by a metal deposited on the surface of the barrier metal film, and the substrate can be free from exposure to a nitrogen-containing gas plasma. Consequently, a barrier metal film production apparatus can be achieved which is capable of forming a barrier metal film at a high speed with excellent burial properties without exerting the influence of the nitrogen-containing gas plasma upon the substrate, and also forming a barrier metal film with excellent adhesion to a metal formed as a film on the surface of the barrier metal film.
• The barrier metal film production apparatus may further comprise hydrogen gas supply means for supplying a hydrogen gas into the chamber; and hydroxyl group plasma generation means which converts the atmosphere within the chamber into a plasma to generate a hydrogen gas plasma so that hydroxyl groups are formed on the oxide layer.
• Thus, hydroxyl groups are formed, so that hydrophilicity can be increased, and adhesion of a metal deposited on the surface can be further increased.
• According to the present invention, there is also provided a barrier metal film production method comprising:
• supplying a source gas containing a halogen and a nitrogen-containing gas to an interior of a chamber between a substrate and a metallic etched member;
• converting an atmosphere within the chamber into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas, and also converting the atmosphere within the chamber into a plasma to generate a nitrogen-containing gas plasma so that a metal nitride is formed upon reaction between nitrogen and the precursor;
• making a temperature of the substrate lower than a temperature of plasma generation means to form the metal nitride as a barrier metal film on a surface of the substrate;
• supplying a diluent gas to a site within the chamber above the surface of the substrate; and
• performing a surface treatment which converts the atmosphere within the chamber into a plasma to generate a diluent gas plasma so that nitrogen atoms in a superficial layer of the barrier metal film are removed by the diluent gas plasma to decrease a nitrogen content of the superficial layer relative to an interior of a matrix of the barrier metal film.
• Thus, a barrier metal film comprising a metal nitride layer and a metal layer can be prepared without the increase of the film thickness. Consequently, a barrier metal film production method can be achieved which is capable of forming a barrier metal film at a high speed with excellent burial properties in a very small thickness, and also forming a barrier metal film with excellent adhesion to a metal formed as a film on the surface of the barrier metal film.
• The barrier metal film production method may further comprise supplying an oxygen gas into the chamber immediately before formation of the most superficial layer of the barrier metal film is completed; and converting the atmosphere within the chamber into a plasma to generate an oxygen gas plasma so that an oxide layer is formed on the most superficial layer of the barrier metal film.
• Thus, the oxide layer gives satisfactory wettability by a metal deposited on the surface of the barrier metal film, thereby increasing adhesion to the metal.
• According to the present invention, there is also provided a barrier metal film production method comprising:
• supplying a source gas containing a halogen and a nitrogen-containing gas to an interior of a chamber between a substrate and a metallic etched member;
• converting an atmosphere within the chamber into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas, and also converting the atmosphere within the chamber into a plasma to generate a nitrogen-containing gas plasma so that a metal nitride is formed upon reaction between nitrogen and the precursor;
• making a temperature of the substrate lower than a temperature of plasma generation means to form the metal nitride as a barrier metal film on a surface of the substrate;
• supplying an oxygen gas to a site above the surface of the substrate; and
• performing a surface treatment which converts the atmosphere within the chamber into a plasma to generate an oxygen gas plasma so that nitrogen atoms in a superficial layer of the barrier metal film are removed by the oxygen gas plasma to decrease a nitrogen content of the superficial layer relative to an interior of a matrix of the barrier metal film, while forming an oxide layer on the most superficial layer of the barrier metal film.
• Thus, a barrier metal film comprising a metal nitride layer and a metal layer can be prepared with a minimum nozzle construction without the increase of the film thickness, and an oxide layer gives satisfactory wettability by a metal deposited on the surface of the barrier metal film. Consequently, a barrier metal film production method can be achieved which is capable of forming a barrier metal film at a high speed with excellent burial properties in a very small thickness, and also forming a barrier metal film with excellent adhesion to a metal formed as a film on the surface of the barrier metal film.
• According to the present invention, there is also provided a barrier metal film production method comprising:
• supplying a source gas containing a halogen and a nitrogen-containing gas to an interior of a chamber between a substrate and a metallic etched member;
• converting an atmosphere within the chamber into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas, and also converting the atmosphere within the chamber into a plasma to generate a nitrogen-containing gas plasma so that a metal nitride is formed upon reaction between nitrogen and the precursor;
• making a temperature of the substrate lower than a temperature of plasma generation means to form the metal nitride as a film on a surface of the substrate for use as a barrier metal film;
• supplying an oxygen gas into the chamber immediately before formation of the most superficial layer of the barrier metal film is completed; and
• converting the atmosphere within the chamber into a plasma to generate an oxygen gas plasma so that an oxide layer is formed on the most superficial layer of the barrier metal film.
• Thus, a barrier metal film comprising a metal nitride layer can be prepared without the increase of the film thickness, and an oxide layer gives satisfactory wettability by a metal deposited on the surface of the barrier metal film. Consequently, a barrier metal film production method can be achieved which is capable of forming a barrier metal film at a high speed with excellent burial properties in a very small thickness, and also forming a barrier metal film with excellent adhesion to a metal formed as a film on the surface of the barrier metal film.
• According to the present invention, there is also provided a barrier metal film production method comprising:
• supplying a source gas containing a halogen and a nitrogen-containing gas to an interior of a chamber between a substrate and a metallic etched member;
• converting an atmosphere within the chamber into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas, and also converting the atmosphere within the chamber into a plasma to generate a nitrogen-containing gas plasma so that a metal nitride is formed upon reaction between nitrogen and the precursor;
• making a temperature of the substrate lower than a temperature of plasma generation means to form the metal nitride as a film on a surface of the substrate, then making the temperature of the substrate lower than the temperature of the plasma generation means and stopping supply of the gas containing nitrogen, thereby forming the metal component of the precursor as a film on the metal nitride for use as a barrier metal film;
• supplying an oxygen gas into the chamber immediately before formation of the most superficial layer of the barrier metal film is completed; and
• converting the atmosphere within the chamber into a plasma to generate an oxygen gas plasma so that an oxide layer is formed on the most superficial layer of the barrier metal film.
• Thus, a barrier metal film comprising a metal nitride layer and a metal layer can be prepared without the increase of the film thickness, and an oxide layer gives satisfactory wettability by a metal deposited on the surface of the barrier metal film. Consequently, a barrier metal film production method can be achieved which is capable of forming a barrier metal film at a high speed with excellent burial properties, and also forming a barrier metal film with excellent adhesion to a metal formed as a film on the surface of the barrier metal film.
• According to the present invention, there is also provided a barrier metal film production method comprising:
• supplying a source gas containing a halogen and a nitrogen-containing gas to an interior of a chamber between a substrate and a metallic etched member;
• converting an atmosphere within the chamber into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas, and also exciting the gas containing nitrogen in a manner isolated from the chamber accommodating the substrate;
• forming a metal nitride upon reaction between excited nitrogen and the precursor;
• making a temperature of the substrate lower than a temperature of means for formation of the metal nitride to form the metal nitride as a film on the substrate for use as a barrier metal film;
• supplying an oxygen gas at a site above a surface of the substrate immediately before formation of the most superficial layer of the barrier metal film is completed; and
• converting the atmosphere within the chamber into a plasma to generate an oxygen gas plasma so that an oxide layer is formed on the most superficial layer of the barrier metal film.
• Thus, a barrier metal film comprising a metal nitride layer can be prepared without the increase of the film thickness, an oxide layer gives satisfactory wettability by a metal deposited on the surface of the barrier metal film, and the substrate can be free from exposure to a nitrogen-containing gas plasma. Consequently, a barrier metal film production method can be achieved which is capable of forming a barrier metal film at a high speed with excellent burial properties in a very small thickness without exerting the influence of the nitrogen-containing gas plasma upon the substrate, and also forming a barrier metal film with excellent adhesion to a metal formed as a film on the surface of the barrier metal film.
• According to the present invention, there is also provided a barrier metal film production method comprising:
• supplying a source gas containing a halogen and a nitrogen-containing gas to an interior of a chamber between a substrate and a metallic etched member;
• converting an atmosphere within the chamber into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas, and also exciting the gas containing nitrogen in a manner isolated from the chamber accommodating the substrate;
• forming a metal nitride upon reaction between excited nitrogen and the precursor;
• making a temperature of the substrate lower than a temperature of means for formation of the metal nitride to form the metal nitride as a film on the substrate, and after film formation of the metal nitride, stopping supply of the nitrogen-containing gas and making the temperature of the substrate lower than a temperature of the etched member, thereby forming the metal component of the precursor as a film on the metal nitride on the substrate for use as a barrier metal film;
• supplying an oxygen gas at a site above a surface of the substrate immediately before formation of the most superficial layer of the barrier metal film is completed; and
• converting the atmosphere within the chamber into a plasma to generate an oxygen gas plasma so that an oxide layer is formed on the most superficial layer of the barrier metal film.
• Thus, a barrier metal film comprising a metal nitride layer can be prepared without the increase of the film thickness, an oxide layer gives satisfactory wettability by a metal deposited on the surface of the barrier metal film, and the substrate can be free from exposure to a nitrogen-containing gas plasma. Consequently, a barrier metal film production method can be achieved which is capable of forming a barrier metal film at a high speed with excellent burial properties without exerting the influence of the nitrogen-containing gas plasma upon the substrate, and also forming a barrier metal film with excellent adhesion to a metal formed as a film on the surface of the barrier metal film.
• The barrier metal film production method may further comprise supplying a hydrogen gas into the chamber; and converting the atmosphere within the chamber into a plasma to generate a hydrogen gas plasma so that hydroxyl groups are formed on the oxide layer.
• Thus, hydrophilicity can be increased, so that adhesion of a metal deposited on the surface can be further increased.
• According to the present invention, there is also provided a barrier metal film production method involving treatment of a surface of a substrate having a barrier metal film of a metal nitride formed thereon, comprising:
• performing a surface treatment which removes nitrogen atoms in a superficial layer of the barrier metal film to decrease a nitrogen content of the superficial layer relative to an interior of a matrix of the barrier metal film, thereby substantially forming a metal layer on the superficial layer.
• Thus, the substantial metal layer and the metal nitride layer can be formed with a single-layer thickness, and a barrier metal film with a very small thickness can be produced, with diffusion of metal being prevented and adhesion to the metal being retained. Consequently, a metal wiring process can be stabilized.
• According to the present invention, there is also provided a metal film comprising a metal layer substantially formed on a superficial layer of a barrier metal film of a metal nitride formed on a surface of a substrate, said metal layer being formed by performing a surface treatment which removes nitrogen atoms in the superficial layer of the barrier metal film to decrease a nitrogen content of the superficial layer relative to an interior of a matrix of the barrier metal film.
• Thus, there is obtained a metal film which has a barrier metal film comprising the substantial metal layer and the metal nitride layer formed with a single-layer thickness, and produced with a very small thickness, with diffusion of metal being prevented and adhesion to the metal being retained, and which can stabilize a metal wiring process.
• According to the present invention, there is also provided a barrier metal film production method involving treatment of a surface of a substrate having a barrier metal film of a metal nitride formed thereon, comprising:
• performing a surface treatment which etches the barrier metal film on the surface of the substrate with a diluent gas plasma to flatten the barrier metal film.
• Thus, a barrier metal film can be produced, with diffusion of metal being prevented and adhesion to the metal being retained. Consequently, a metal wiring process can be stabilized.
• According to the present invention, there is also provided a barrier metal film production method involving treatment of a surface of a substrate having a barrier metal film of a metal nitride formed thereon, comprising:
• performing a surface treatment which etches the barrier metal film on the surface of the substrate with a diluent gas plasma to flatten the barrier metal film, and removes nitrogen atoms in a superficial layer of the barrier metal film by the diluent gas plasma to decrease a nitrogen content of the superficial layer relative to an interior of a matrix of the barrier metal film.
• Thus, the substantial metal layer and the metal nitride layer can be formed with a single-layer thickness, and a barrier metal film with a very small thickness can be produced, with diffusion of metal being prevented and adhesion to the metal being retained. Consequently, a metal wiring process can be stabilized.
• According to the present invention, there is also provided a metal film production method comprising:
• supplying a source gas containing a halogen to an interior of a chamber between a substrate and a metallic etched member;
• converting an atmosphere within the chamber into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas, and also exciting a gas containing nitrogen in a manner isolated from the chamber accommodating the substrate;
• forming a metal nitride upon reaction between excited nitrogen and the precursor;
• making a temperature of the substrate lower than a temperature of means for formation of the metal nitride to form the metal nitride as a film on the substrate for use as a barrier metal film; and
• performing a surface treatment which etches the barrier metal film on a surface of the substrate with a diluent gas plasma to flatten the barrier metal film.
• Thus, a barrier metal film can be produced such that the barrier metal film is prepared, and then subjected to a treatment for preventing diffusion of metal and retaining adhesion to the metal. Consequently, a metal wiring process can be stabilized.
• According to the present invention, there is also provided a metal film production method comprising:
• supplying a source gas containing a halogen to an interior of a chamber between a substrate and a metallic etched member;
• converting an atmosphere within the chamber into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas, and also exciting a gas containing nitrogen in a manner isolated from the chamber accommodating the substrate;
• forming a metal nitride upon reaction between excited nitrogen and the precursor;
• making a temperature of the substrate lower than a temperature of means for formation of the metal nitride to form the metal nitride as a film on the substrate for use as a barrier metal film; and
• performing a surface treatment which etches the barrier metal film on a surface of the substrate with a diluent gas plasma to flatten the barrier metal film, and removes nitrogen atoms in a superficial layer of the barrier metal film by the diluent gas plasma to decrease a nitrogen content of the superficial layer relative to an interior of a matrix of the barrier metal film.
• Thus, after a barrier metal film is prepared, the substantial metal layer and the metal nitride layer can be formed with a single-layer thickness. Hence, a barrier metal film having a very small thickness can be produced, with diffusion of metal being prevented and adhesion to the metal being retained. Consequently, a metal wiring process can be stabilized.
• According to the present invention, there is also provided a metal film production method comprising:
• performing a surface treatment which generates a diluent gas plasma within a chamber accommodating a substrate having a barrier metal film of a metal nitride formed thereon, to etch the barrier metal film on a surface of the substrate with the diluent gas plasma, thereby flattening the barrier metal film;
• then supplying a source gas containing a halogen into the chamber;
• converting an atmosphere within the chamber into a plasma to generate a source gas plasma so that an etched member made of a metal is etched with the source gas plasma to form a precursor within the chamber from a metal component contained in the etched member and the source gas; and
• making a temperature of the substrate lower than a temperature of the etched member to form the metal component of the precursor as a film on the substrate having the barrier metal film flattened.
• Thus, a metal can be formed as a film through the production of a barrier metal film subjected to a treatment for preventing diffusion of metal and retaining adhesion to the metal. Consequently, a metal wiring process can be stabilized.
• According to the present invention, there is also provided a metal film production method comprising:
• performing a surface treatment which generates a diluent gas plasma within a chamber accommodating a substrate having a barrier metal film of a metal nitride formed thereon, to etch the barrier metal film on a surface of the substrate with the diluent gas plasma, thereby flattening the barrier metal film, and removes nitrogen atoms in a superficial layer of the barrier metal film by the diluent gas plasma to decrease a nitrogen content of the superficial layer relative to an interior of a matrix of the barrier metal film;
• then supplying a source gas containing a halogen into the chamber;
• converting an atmosphere within the chamber into a plasma to generate a source gas plasma so that an etched member made of a metal is etched with the source gas plasma to form a precursor within the chamber from a metal component contained in the etched member and the source gas; and
• making a temperature of the substrate lower than a temperature of the etched member to form the metal component of the precursor as a film on the substrate having the barrier metal film flattened and having the nitrogen content of the superficial layer relatively decreased.
• Thus, the substantial metal layer and the metal nitride layer can be formed with a single-layer thickness. Hence, a metal can be formed as a film through the production of a barrier metal film having a very small thickness while preventing diffusion of metal and retaining adhesion to the metal. Consequently, a metal wiring process can be stabilized.
• The metal film production method may further comprise applying a densification treatment for densifying metal atoms in a superficial layer of the barrier metal film after flattening the barrier metal film and also relatively decreasing the nitrogen content of the superficial layer.
• Thus, diffusion of the component of the metal film can be prevented reliably.
• In the metal film production method, the diluent gas plasma may be an argon gas plasma. Thus, the treatment can be performed reliably with the use of an inexpensive gas.
• According to the present invention, there is also provided a metal film production apparatus, comprising:
• a chamber accommodating a substrate;
• a metallic etched member provided in the chamber at a position opposed to the substrate;
• halogen gas supply means for supplying a source gas containing a halogen to an interior of the chamber between the substrate and the etched member;
• barrier plasma generation means which converts an atmosphere within the chamber into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas;
• excitation means for exciting a gas containing nitrogen in a manner isolated from the chamber;
• formation means for forming a metal nitride upon reaction between nitrogen excited by the excitation means and the precursor;
• control means which makes a temperature of the substrate lower than a temperature of the formation means to form the metal nitride as a film on the substrate for use as a barrier metal film;
• diluent gas supply means for supplying a diluent gas to a site above a surface of the substrate; and
• surface treatment plasma generation means which converts the atmosphere within the chamber into a plasma to generate a diluent gas plasma so that the barrier metal film on the surface of the substrate is etched with the diluent gas plasma to flatten the barrier metal film.
• Thus, there can be produced a barrier metal film subjected to treatment for preventing diffusion of metal and retaining adhesion to the metal. Consequently, a metal wiring process can be stabilized.
• According to the present invention, there is also provided a metal film production apparatus, comprising:
• a chamber accommodating a substrate;
• a metallic etched member provided in the chamber at a position opposed to the substrate;
• halogen gas supply means for supplying a source gas containing a halogen to an interior of the chamber between the substrate and the etched member;
• barrier plasma generation means which converts an atmosphere within the chamber into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas;
• excitation means for exciting a gas containing nitrogen in a manner isolated from the chamber;
• formation means for forming a metal nitride upon reaction between nitrogen excited by the excitation means and the precursor;
• control means which makes a temperature of the substrate lower than a temperature of the formation means to form the metal nitride as a film on the substrate for use as a barrier metal film;
• diluent gas supply means for supplying a diluent gas to a site above a surface of the substrate; and
• surface treatment plasma generation means for performing a surface treatment which converts the atmosphere within the chamber into a plasma to generate a diluent gas plasma so that the barrier metal film on the surface of the substrate is etched with the diluent gas plasma to flatten the barrier metal film, and removes nitrogen atoms in a superficial layer of the barrier metal film to decrease a nitrogen content of the superficial layer relative to an interior of a matrix of the barrier metal film.
• Thus, the substantial metal layer and the metal nitride layer can be formed with a single-layer thickness. Hence, a barrier metal film having a very small thickness can be produced, with diffusion of metal being prevented and adhesion to the metal being retained. Consequently, a metal wiring process can be stabilized.
• According to the present invention, there is also provided a metal film production apparatus, comprising:
• a chamber accommodating a substrate having a barrier metal film of a metal nitride formed thereon;
• diluent gas supply means for supplying a diluent gas to an interior of the chamber above a surface of the substrate;
• surface treatment plasma generation means which converts an atmosphere within the chamber into a plasma to generate a diluent gas plasma so that the barrier metal film on the surface of the substrate is etched with the diluent gas plasma to flatten the barrier metal film;
• a metallic etched member provided in the chamber;
• source gas supply means for supplying a source gas containing a halogen to an interior of the chamber between the substrate and the etched member;
• plasma generation means which converts the source gas containing the halogen into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas; and
• control means which makes a temperature of the substrate lower than a temperature of the etched member to form the metal component of the precursor as a film on the flattened barrier metal film.
• Thus, a metal film can be formed through the production of a barrier metal film subjected to a treatment for preventing diffusion of metal and retaining adhesion to the metal. Consequently, a metal wiring process can be stabilized.
• According to the present invention, there is also provided a metal film production apparatus, comprising:
• a chamber accommodating a substrate having a barrier metal film of a metal nitride formed thereon;
• diluent gas supply means for supplying a diluent gas to an interior of the chamber above a surface of the substrate;
• surface treatment plasma generation means which converts an atmosphere within the chamber into a plasma to generate a diluent gas plasma so that the barrier metal film on the surface of the substrate is etched with the diluent gas plasma to flatten the barrier metal film, and also removes nitrogen atoms in a superficial layer of the barrier metal film by the diluent gas plasma to decrease a nitrogen content of the superficial layer relative to an interior of a matrix of the barrier metal film;
• a metallic etched member provided in the chamber;
• source gas supply means for supplying a source gas containing a halogen to an interior of the chamber between the substrate and the etched member;
• plasma generation means which converts the source gas containing the halogen into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas; and
• control means which makes a temperature of the substrate lower than a temperature of the etched member to form the metal component of the precursor as a film on the barrier metal film flattened and having the nitrogen content of the superficial layer relatively decreased.
• Thus, the substantial metal layer and the metal nitride layer can be formed with a single-layer thickness. Hence, a metal film can be formed through the production of a barrier metal film having a very small thickness while preventing diffusion of metal and retaining adhesion to the metal. Consequently, a metal wiring process can be stabilized.
• The metal film production apparatus may further comprise densification treatment means for densifying metal atoms in the superficial layer after flattening the barrier metal film and also relatively decreasing the nitrogen content of the superficial layer. Thus, diffusion of the component of the metal film can be prevented reliably.
• In the metal film production apparatus, the diluent gas plasma may be an argon gas plasma. Thus, the treatment can be performed reliably with the use of an inexpensive gas.
• According to the present invention, there is also provided a metal film formed by flattening a barrier metal film of a metal nitride on a surface of a substrate by etching with a diluent gas plasma.
• Thus, the resulting metal film has a barrier metal film retaining adhesion, and can stabilize a metal wiring process.
• According to the present invention, there is also provided a metal film formed by a surface treatment which flattens a barrier metal film of a metal nitride on a surface of a substrate by etching with a diluent gas plasma, and removes nitrogen atoms in a superficial layer of the barrier metal film by the diluent gas plasma to decrease a nitrogen content of the superficial layer relative to an interior of a matrix of the barrier metal film.
• Thus, there is obtained a metal film which has a barrier metal film comprising the substantial metal layer and the metal nitride layer formed with a single-layer thickness, and produced with a very small thickness, with diffusion of metal being prevented and adhesion to the metal being retained, and which can stabilize a metal wiring process.
• According to the present invention, there is also provided a metal film production method involving treatment of a surface of a substrate having a barrier metal film of a metal nitride formed thereon, comprising:
• performing a surface treatment which reacts the barrier metal film on the surface of the substrate in a reducing gas atmosphere to remove nitrogen atoms in a superficial layer of the barrier metal film, thereby decreasing a nitrogen content of the superficial layer relative to an interior of a matrix of the barrier metal film.
• Thus, a barrier metal film with a very small thickness and comprising the substantial metal layer and the metal nitride layer formed with a single-layer thickness can be produced, with diffusion of metal being prevented and adhesion to the metal being retained. Consequently, a metal wiring process can be stabilized.
• According to the present invention, there is also provided a metal film production method comprising:
• supplying a source gas containing a halogen to an interior of a chamber between a substrate and a metallic etched member;
• converting an atmosphere within the chamber into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas, and also exciting a gas containing nitrogen in a manner isolated from the chamber accommodating the substrate;
• forming a metal nitride upon reaction between excited nitrogen and the precursor;
• making a temperature of the substrate lower than a temperature of means for formation of the metal nitride to form the metal nitride as a film on the substrate for use as a barrier metal film; and
• performing a surface treatment which reacts the barrier metal film on a surface of the substrate in a reducing gas atmosphere to remove nitrogen atoms in a superficial layer of the barrier metal film, thereby decreasing a nitrogen content of the superficial layer relative to an interior of a matrix of the barrier metal film.
• Thus, a barrier metal film with a very small thickness and comprising the substantial metal layer and the metal nitride layer formed with a single-layer thickness can be produced, with diffusion of metal being prevented and adhesion to the metal being retained. Consequently, a metal wiring process can be stabilized.
• According to the present invention, there is also provided a metal film production method comprising:
• performing a surface treatment in a chamber accommodating a substrate having a barrier metal film of a metal nitride formed thereon, said surface treatment comprising reacting the barrier metal film on a surface of the substrate in a reducing gas atmosphere to remove nitrogen atoms in a superficial layer of the barrier metal film, thereby decreasing a nitrogen content of the superficial layer relative to an interior of a matrix of the barrier metal film;
• then supplying a source gas containing a halogen into the chamber;
• converting an atmosphere within the chamber into a plasma to generate a source gas plasma so that a metallic etched member is etched with the source gas plasma to form a precursor within the chamber from a metal component contained in the etched member and the source gas; and
• making a temperature of the substrate lower than a temperature of the etched member to form the metal component of the precursor as a film on the substrate having the barrier metal film flattened thereon.
• Thus, a metal film can be formed through the production of a barrier metal film having a very small thickness and comprising the substantial metal layer and the metal nitride layer formed with a single-layer thickness, while preventing diffusion of metal and retaining adhesion to the metal. Consequently, a metal wiring process can be stabilized.
• According to the present invention, there is also provided a metal film production apparatus, comprising:
• a chamber accommodating a substrate;
• a metallic etched member provided in the chamber at a position opposed to the substrate;
• halogen gas supply means for supplying a source gas containing a halogen to an interior of the chamber between the substrate and the etched member;
• barrier plasma generation means which converts an atmosphere within the chamber into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas;
• excitation means for exciting a gas containing nitrogen in a manner isolated from the chamber;
• formation means for forming a metal nitride upon reaction between nitrogen excited by the excitation means and the precursor;
• control means which makes a temperature of the substrate lower than a temperature of the formation means to form the metal nitride as a film on the substrate for use as a barrier metal film;
• reducing gas supply means for supplying a reducing gas to a site above a surface of the substrate; and
• surface treatment means which reacts the barrier metal film on the surface of the substrate in a reducing gas atmosphere to remove nitrogen atoms in a superficial layer of the barrier metal film, thereby decreasing a nitrogen content of the superficial layer relative to an interior of a matrix of the barrier metal film.
• Thus, a barrier metal film with a very small thickness and comprising the substantial metal layer and the metal nitride layer formed with a single-layer thickness can be produced, with diffusion of metal being prevented and adhesion to the metal being retained. Consequently, a metal wiring process can be stabilized.
• According to the present invention, there is also provided a metal film production apparatus, comprising:
• a chamber accommodating a substrate having a barrier metal film of a metal nitride formed thereon;
• reducing gas supply means for supplying a reducing gas to a site above a surface of the substrate;
• surface treatment means which reacts the barrier metal film on the surface of the substrate in a reducing gas atmosphere to remove nitrogen atoms in a superficial layer of the barrier metal film, thereby decreasing a nitrogen content of the superficial layer relative to an interior of a matrix of the barrier metal film;
• a metallic etched member provided in the chamber;
• source gas supply means for supplying a source gas containing a halogen to an interior of the chamber between the substrate and the etched member;
• plasma generation means which converts the source gas containing the halogen into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas; and
• control means which makes a temperature of the substrate lower than a temperature of the etched member to form the metal component of the precursor as a film on the barrier metal film having the nitrogen content of the superficial layer relatively decreased.
• Thus, a metal film can be formed through the production of a barrier metal film having a very small thickness and comprising the substantial metal layer and the metal nitride layer formed with a single-layer thickness, while preventing diffusion of metal and retaining adhesion to the metal. Consequently, a metal wiring process can be stabilized.
• According to the present invention, there is also provided a metal film formed by a surface treatment which reacts a barrier metal film of a metal nitride on a surface of a substrate in a reducing gas atmosphere to remove nitrogen atoms in a superficial layer of the barrier metal film, thereby decreasing a nitrogen content of the superficial layer relative to an interior of a matrix of the barrier metal film.
• Thus, there is obtained a metal film which has a barrier metal film comprising the substantial metal layer and the metal nitride layer formed with a single-layer thickness, and produced with a very small thickness, with diffusion of metal being prevented and adhesion to the metal being retained, and which can stabilize a metal wiring process.
• According to the present invention, there is also provided a metal film production method involving treatment of a surface of a substrate having a barrier metal film of a metal nitride formed thereon, comprising:
• performing a surface treatment which forms nuclei of silicon atoms on a surface of the barrier metal film on the surface of the substrate by a gas plasma containing silicon.
• Thus, a barrier metal film with a very small thickness can be produced, with adhesion to metal being retained. Consequently, a metal wiring process can be stabilized.
• According to the present invention, there is also provided a metal film production method comprising:
• supplying a source gas containing a halogen to an interior of a chamber between a substrate and a metallic etched member;
• converting an atmosphere within the chamber into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas, and also exciting a gas containing nitrogen in a manner isolated from the chamber accommodating the substrate;
• forming a metal nitride upon reaction between excited nitrogen and the precursor;
• making a temperature of the substrate lower than a temperature of means for formation of the metal nitride to form the metal nitride as a film on the substrate for use as a barrier metal film; and
• performing a surface treatment which forms nuclei of silicon atoms on a surface of the barrier metal film on a surface of the substrate by a gas plasma containing silicon.
• Thus, a barrier metal film with a very small thickness can be produced, with adhesion to metal being retained. Consequently, a metal wiring process can be stabilized.
• According to the present invention, there is also provided a metal film production method comprising:
• performing a surface treatment in a chamber accommodating a substrate having a barrier metal film of a metal nitride formed thereon, said surface treatment comprising forming nuclei of silicon atoms on a surface of the barrier metal film on a surface of the substrate by a gas plasma containing silicon;
• then supplying a source gas containing a halogen into the chamber;
• converting an atmosphere within the chamber into a plasma to generate a source gas plasma so that a metallic etched member is etched with the source gas plasma to form a precursor within the chamber from a metal component contained in the etched member and the source gas; and
• making a temperature of the substrate lower than a temperature of the etched member to form the metal component of the precursor as a film on the substrate having the nuclei of silicon atoms formed on the surface of the barrier metal film.
• Thus, a metal film can be formed through the production of a barrier metal film having a very small thickness and retaining adhesion to metal. Consequently, a metal wiring process can be stabilized.
• According to the present invention, there is also provided a metal film production apparatus, comprising:
• a chamber accommodating a substrate;
• a metallic etched member provided in the chamber at a position opposed to the substrate;
• halogen gas supply means for supplying a source gas containing a halogen to an interior of the chamber between the substrate and the etched member;
• barrier plasma generation means which converts an atmosphere within the chamber into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas;
• excitation means for exciting a gas containing nitrogen in a manner isolated from the chamber;
• formation means for forming a metal nitride upon reaction between nitrogen excited by the excitation means and the precursor;
• control means which makes a temperature of the substrate lower than a temperature of the formation means to form the metal nitride as a film on the substrate for use as a barrier metal film;
• silicon-containing gas supply means for supplying a gas containing silicon to a site above a surface of the substrate; and
• surface treatment plasma generation means which generates a gas plasma containing silicon to form nuclei of silicon atoms on a surface of the barrier metal film on the surface of the substrate.
• Thus, a barrier metal film with a very small thickness can be produced, with adhesion to metal being retained. Consequently, a metal wiring process can be stabilized.
• According to the present invention, there is also provided a metal film production apparatus, comprising:
• a chamber accommodating a substrate having a barrier metal film of a metal nitride formed thereon;
• silicon-containing gas supply means for supplying a gas containing silicon to a site above a surface of the substrate;
• surface treatment plasma generation means which generates a gas plasma containing silicon to form nuclei of silicon atoms on a surface of the barrier metal film on the surface of the substrate;
• a metallic etched member provided in the chamber;
• source gas supply means for supplying a source gas containing a halogen to an interior of the chamber between the substrate and the etched member;
• plasma generation means which converts the source gas containing the halogen into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas; and
• control means which makes a temperature of the substrate lower than a temperature of the etched member to form the metal component of the precursor as a film on the barrier metal film having the nuclei of silicon atoms formed on the surface thereof.
• Thus, a metal film can be formed through the production of a barrier metal film having a very small thickness and retaining adhesion to metal. Consequently, a metal wiring process can be stabilized.
• According to the present invention, there is also provided a metal film formed by applying a surface treatment to a barrier metal film of a metal nitride on a surface of a substrate such that nuclei of silicon atoms are formed on a surface of the barrier metal film on the surface of the substrate by a gas plasma containing silicon.
• Thus, there is obtained a metal film which has a barrier metal film having a very small thickness and retaining adhesion to metal, and which can stabilize a metal wiring process.
BRIEF DESCRIPTION OF THE DRAWINGS
• The present invention will become more fully understood from the detailed description given hereinbelow and the accompanying drawings which are given by way of illustration only, and thus are not limitative of the present invention, and wherein:
• FIG. 1 is a schematic side view of a barrier metal film production apparatus according to a first embodiment of the present invention;
• FIG. 2 is a detail view of a substrate on which a barrier metal film has been produced;
• FIG. 3 is a schematic side view of a barrier metal film production apparatus according to a second embodiment of the present invention;
• FIG. 4 is a view taken along the arrowed line IV-IV ofFIG. 3;
• FIG. 5 is a view taken along the arrowed line V-V ofFIG. 4;
• FIG. 6 is a schematic side view of a barrier metal film production apparatus according to a third embodiment of the present invention;
• FIG. 7 is a schematic side view of a barrier metal film production apparatus according to a fourth embodiment of the present invention;
• FIG. 8 is a schematic side view of a barrier metal film production apparatus according to a fifth embodiment of the present invention;
• FIG. 9 is a schematic side view of a barrier metal film production apparatus according to a sixth embodiment of the present invention;
• FIG. 10 is a schematic side view of a barrier metal film production apparatus according to a seventh embodiment of the present invention;
• FIG. 11 is a schematic side view of a barrier metal film production apparatus according to an eighth embodiment of the present invention;
• FIG. 12 is a schematic side view of a barrier metal film production apparatus according to a ninth embodiment of the present invention;
• FIG. 13 is a sectional view of a substrate illustrating a barrier metal film;
• FIG. 14 is a concept view of a barrier metal film in a treatment for denitrification;
• FIG. 15 is a concept view of the barrier metal film in the treatment for denitrification;
• FIG. 16 is a concept view of a barrier metal film in a treatment for oxide layer formation;
• FIG. 17 is a graph representing the relationship between the contact angle of copper particles and the oxygen concentration of the substrate;
• FIG. 18 is a concept view of a barrier metal film in a treatment for hydroxyl group formation;
• FIG. 19 is a schematic construction drawing showing another example of diluent gas supply means;
• FIG. 20 is a schematic construction drawing of a barrier metal film production apparatus according to a tenth embodiment of the present invention;
• FIG. 21 is a concept view of an example of production of a barrier metal film by the barrier metal film production apparatus according to the tenth embodiment of the present invention;
• FIG. 22 is a schematic side view of a barrier metal film production apparatus according to an eleventh embodiment of the present invention;
• FIG. 23 is a schematic side view of a barrier metal film production apparatus according to a twelfth embodiment of the present invention;
• FIG. 24 is a view taken along the arrowed line XIII-XIII ofFIG. 23;
• FIG. 25 is a view taken along the arrowed line XIV-XIV ofFIG. 24;
• FIG. 26 is a schematic side view of a barrier metal film production apparatus according to a thirteenth embodiment of the present invention;
• FIG. 27 is a schematic side view of a barrier metal film production apparatus according to a fourteenth embodiment of the present invention;
• FIG. 28 is an outline drawing of an apparatus for a film formation process;
• FIG. 29 is a schematic side view of a metal film production apparatus according to a fifteenth embodiment of the present invention;
• FIG. 30 is a schematic construction drawing showing another example of diluent gas supply means;
• FIG. 31 is a sectional view of a substrate illustrating a barrier metal film;
• FIG. 32 is a concept view of a barrier metal film in a treatment for denitrification;
• FIG. 33 is a concept view of the barrier metal film in the treatment for denitrification;
• FIG. 34 is a schematic side view of a metal film production apparatus according to a sixteenth embodiment of the present invention;
• FIG. 35 is a view taken along the arrowed line VIII-VIII ofFIG. 34;
• FIG. 36 is a view taken along the arrowed line IX-IX ofFIG. 35;
• FIG. 37 is a schematic side view of a metal film production apparatus according to a seventeenth embodiment of the present invention;
• FIG. 38 is a schematic side view of a metal film production apparatus according to an eighteenth embodiment of the present invention;
• FIG. 39 is a schematic side view of a metal film production apparatus according to a nineteenth embodiment of the present invention;
• FIG. 40 is a conceptual construction drawing of a metal film production apparatus according to a twentieth embodiment of the present invention;
• FIG. 41 is a concept view of a barrier metal film in a treatment for denitrification;
• FIG. 42 is a schematic construction drawing of a metal film production apparatus according to a twenty-first embodiment of the present invention; and
• FIG. 43 is a concept view of a barrier metal film in formation of nuclei of Si.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
• The first embodiment of the barrier metal film production apparatus and barrier metal film production method of the present invention will be described with reference toFIGS. 1 and 2.FIG. 1 is a schematic side view of the barrier metal film production apparatus according to the first embodiment of the present invention.FIG. 2 shows details of a substrate on which a barrier metal film has been prepared.
• As shown in the drawings, asupport platform2 is provided near the bottom of acylindrical chamber1 made of, say, a ceramic (an insulating material), and asubstrate3 is placed on thesupport platform2. Temperature control means6 equipped with aheater4 and refrigerant flow-throughmeans5 is provided in thesupport platform2 so that thesupport platform2 is controlled to a predetermined temperature (for example, a temperature at which thesubstrate3 is maintained at 100 to 200° C.) by the temperature control means6.
• An upper surface of thechamber1 is an opening, which is closed with ametal member7, as an etched member, made of a metal (e.g., W, Ti, Ta, or TiSi). The interior of thechamber1 closed with themetal member7 is maintained at a predetermined pressure by avacuum device8. Aplasma antenna9, as a coiled windingantenna9 of plasma generation means, is provided around a cylindrical portion of thechamber1. A matchinginstrument10 and apower source11 are connected to theplasma antenna9 to supply power.
• Nozzles12 for supplying a source gas (a Cl₂gas diluted with He or Ar to a chlorine concentration of ≦50%, preferably about 10%), containing chlorine as a halogen, to the interior of thechamber1 are connected to the cylindrical portion of thechamber1 below themetal member7. Thenozzle12 is open toward the horizontal, and is fed with the source gas via aflow controller13. Fluorine (F), bromine (Br) or iodine (I) can also be applied as the halogen to be incorporated into the source gas.
• Slit-shapedopening portions14 are formed at a plurality of locations (for example, four locations) in the periphery of a lower part of the cylindrical portion of thechamber1, and one end of atubular passage15 is fixed to each of the openingportions14. Atubular excitation chamber16 made of an insulator is provided halfway through thepassage15, and acoiled plasma antenna17 is provided around theexcitation chamber16. Theplasma antenna17 is connected to amatching instrument18 and apower source19 to receive power. Theplasma antenna17, the matchinginstrument18 and thepower source19 constitute excitation means. Aflow controller20 is connected to the other end of thepassage15, and an ammonia gas (NH₃gas) as a nitrogen-containing gas is supplied into thepassage15 via theflow controller20.
• With the above-described barrier metal film production apparatus, the source gas is supplied through thenozzles12 to the interior of thechamber1, and electromagnetic waves are shot from theplasma antenna9 into thechamber1. As a result, the Cl₂gas is ionized to generate a Cl₂gas plasma (source gas plasma)21. The Cl₂gas plasma21 causes an etching reaction to themetal member7, forming a precursor (M_xCl_y: M is a metal such as W, Ti, Ta or TiSi)22.
• Separately, the NH₃gas is supplied into thepassage15 via theflow controller20 and fed into theexcitation chamber16. By shooting electromagnetic waves from theplasma antenna17 into theexcitation chamber16, the NH₃gas is ionized to generate an NH₃gas plasma23. Since a predetermined differential pressure has been established between the pressure inside thechamber1 and the pressure inside theexcitation chamber16 by thevacuum device8, the excited ammonia of the NH₃gas plasma23 in theexcitation chamber16 is fed to the precursor (M_xCl_y)22 inside thechamber1 through the openingportion14.
• That is, excitation means for exciting the nitrogen-containing gas in theexcitation chamber16 isolated from thechamber1 is constructed. Because of this construction, the metal component of the precursor (M_xCl_y)22 and ammonia react to form a metal nitride (MN) (i.e., formation means). At this time, themetal member7 and theexcitation chamber16 are maintained by the plasmas at predetermined temperatures (e.g., 200 to 400° C.) which are higher than the temperature of thesubstrate3.
• The metal nitride (MN) formed within thechamber1 is transported toward thesubstrate3 controlled to a low temperature, whereby athin MN film24 is formed on the surface of thesubstrate3. After thethin MN film24 is formed, the supply of the NH₃gas and the supply of power to thepower source19 are cut off. Thus, the precursor (M_xCl_y)22 is transported toward thesubstrate3 controlled to a lower temperature than the temperature of themetal member7. The precursor (M_xCl_y)22 transported toward thesubstrate3 is converted into only metal (M) ions by a reduction reaction, and directed at thesubstrate3 to form a thin M film25 on thethin MN film24 on thesubstrate3. Abarrier metal film26 is composed of thethin MN film24 and the thin M film25 (seeFIG. 2).
• The reaction for formation of thethin MN film24 can be expressed by:
  2MCl+2NH₃→2MN↓+HCl↑+2H₂↑
• The reaction for formation of the thin M film25 can be expressed by:
  2MCl→2M↓+Cl₂↑
• The gases and the etching products that have not been involved in the reactions are exhausted through anexhaust port27.
• The source gas has been described, with the Cl₂gas diluted with, say, He or Ar taken as an example. However, the Cl₂gas can be used alone, or an HCl gas can also be applied. If the HCl gas is applied, an HCl gas plasma is generated as the source gas plasma. Thus, the source gas may be any gas containing chlorine, and a gas mixture of an HCl gas and a Cl₂gas is also usable. As the material for themetal member7, it is possible to use an industrially applicable metal such as Ag, Au, Pt or Si.
• Thesubstrate3, on which thebarrier metal film26 has been formed, is subjected to a film forming device, which forms a thin copper (Cu) film or a thin aluminum (Al) film on thebarrier metal film26. Because of the presence of thebarrier metal film26, there arise advantages, for example, such that thethin MN film24 eliminates diffusion of Cu into thesubstrate3, and the thin M film25 ensures adhesion of Cu.
• If the material to be formed as a film is a material unproblematic in terms of adhesion (e.g., Al), or if it is a metal to which the nitride can retain adhesion, the thin M film25 can be omitted from thebarrier metal film26. Furthermore, the reduction reaction is caused by the temperature difference. However, a reducing gas plasma can be generated separately to produce a reduction reaction.
• With the above-described barrier metal film production apparatus, the metal is formed by plasmas to produce thebarrier metal film26. Thus, thebarrier metal film26 can be formed uniformly to a small thickness. Consequently, thebarrier metal film26 can be formed highly accurately at a high speed with excellent burial properties in a very small thickness even to the interior of a tiny depression, for example several hundred nanometers wide, which has been provided in thesubstrate3.
• A barrier metal film production apparatus and a barrier metal film production method according to the second embodiment of the present invention will be described with reference to FIGS.3 to5.FIG. 3 is a schematic side view of the barrier metal film production apparatus according to the second embodiment of the present invention.FIG. 4 is a view taken along the arrowed line IV-IV ofFIG. 3.FIG. 5 is a view taken along the arrowed line V-V ofFIG. 4. The same members as the members illustrated inFIG. 1 are assigned the same numerals, and duplicate explanations are omitted.
• An upper surface of thechamber1 is an opening, which is closed with a disk-shapedceiling board30 made of an insulating material (for example, a ceramic). An etchedmember31 made of a metal (e.g., W, Ti, Ta or TiSi) is interposed between the opening at the upper surface of thechamber1 and theceiling board30. The etchedmember31 is provided with aring portion32 fitted into the opening at the upper surface of thechamber1. A plurality of (12 in the illustrated embodiment)protrusions33, which extend close to the center in the diametrical direction of thechamber1 and have the same width, are provided in the circumferential direction on the inner periphery of thering portion32.
• Theprotrusions33 are integrally or removably attached to thering portion32. Notches (spaces)35 formed between theprotrusions33 are present between theceiling board30 and the interior of thechamber1. Thering portion32 is earthed, and theplural protrusions33 are electrically connected together and maintained at the same potential. Temperature control means (not shown), such as a heater, is provided in the etchedmember31 to control the temperature of the etchedmember31 to 200 to 400° C., for example.
• Second protrusions shorter in the diametrical direction than theprotrusions33 can be arranged between theprotrusions33. Moreover, short protrusions can be arranged between theprotrusion33 and the second protrusion. By so doing, the area of copper, an object to be etched, can be secured, with an induced current being suppressed.
• A planar winding-shapedplasma antenna34, for converting the atmosphere inside thechamber1 into a plasma, is provided above theceiling board30. Theplasma antenna34 is formed in a planar ring shape parallel to the surface of theceiling board30. A matchinginstrument10 and apower source11 are connected to theplasma antenna34 to supply power. The etchedmember31 has the plurality ofprotrusions33 provided in the circumferential direction on the inner periphery of thering portion32, and includes the notches (spaces)35 formed between theprotrusions33. Thus, theprotrusions33 are arranged between thesubstrate3 and theceiling board30 in a discontinuous state relative to the flowing direction of electricity in theplasma antenna34.
• With the above-described barrier metal film production apparatus, the source gas is supplied through thenozzles12 to the interior of thechamber1, and electromagnetic waves are shot from theplasma antenna34 into thechamber1. As a result, the Cl₂gas is ionized to generate a Cl₂gas plasma (source gas plasma)21. The etchedmember31, an electric conductor, is present below theplasma antenna34. However, the Cl₂gas plasma21 occurs stably between the etchedmember31 and thesubstrate3, namely, below the etchedmember31, under the following action:
• The action by which the Cl₂gas plasma21 is generated below the etchedmember31 will be described. As shown inFIG. 5, a flow A of electricity in theplasma antenna34 of the planar ring shape crosses theprotrusions33. At this time, an induced current B occurs on the surface of theprotrusion33 opposed to theplasma antenna34. Since the notches (spaces)35 are present in the etchedmember31, the induced current B flows onto the lower surface of eachprotrusion33, forming a flow a in the same direction as the flow A of electricity in the plasma antenna34 (Faraday shield).
• When the etchedmember31 is viewed from thesubstrate3, therefore, there is no flow in a direction in which the flow A of electricity in theplasma antenna34 is canceled out. Furthermore, thering portion32 is earthed, and theprotrusions33 are maintained at the same potential. Thus, even though the etchedmember31, an electric conductor, exists, the electromagnetic wave is reliably thrown from theplasma antenna34 into thechamber1. Consequently, the Cl₂gas plasma21 is stably generated below the etchedmember31.
• Furthermore, plasma generation means composed of apassage15, anexcitation chamber16 and aplasma antenna17 is provided above thesupport platform2.
• The Cl₂gas plasma21 causes an etching reaction to the etchedmember31, forming a precursor (M_xCl_y: M is a metal such as W, Ti, Ta or TiSi)22. In theexcitation chamber16, the NH₃gas is ionized to generate an NH₃gas plasma23. The excited ammonia of the NH₃gas plasma23 in theexcitation chamber16 is fed to the precursor (M_xCl_y)22 inside thechamber1 through the openingportion14. Because of this construction, the metal component of the precursor (M_xCl_y)22 and ammonia react to form a metal nitride (MN) (formation means). At this time, the etchedmember31 and theexcitation chamber16 are maintained by the plasmas at predetermined temperatures (e.g., 200 to 400° C.) which are higher than the temperature of thesubstrate3.
• The metal nitride (MN) formed within thechamber1 is transported toward thesubstrate3 controlled to a low temperature, whereby athin MN film24 is formed on the surface of thesubstrate3. After thethin MN film24 is formed, the supply of the NH₃gas and the supply of power to thepower source19 are cut off. Thus, the precursor (M_xCl_y)22 is transported toward thesubstrate3 controlled to a lower temperature than the temperature of the etchedmember31. The precursor (M_xCl_y)22 transported toward thesubstrate3 is converted into only metal (M) ions by a reduction reaction, and directed at thesubstrate3 to form a thin M film25 on thethin MN film24 on thesubstrate3. Abarrier metal film26 is composed of thethin MN film24 and the thin M film25 (seeFIG. 2). The gases and the etching products, which have not been involved in the reactions, are exhausted through anexhaust port27.
• With the above-described barrier metal film production apparatus, similar to the first embodiment, the metal is formed by plasmas to produce thebarrier metal film26. Thus, thebarrier metal film26 can be formed uniformly to a small thickness. Consequently, thebarrier metal film26 can be formed highly accurately at a high speed with excellent burial properties in a very small thickness even to the interior of a tiny depression, for example several hundred nanometers wide, which has been provided in thesubstrate3.
• In addition, the etchedmember31 has the plurality ofprotrusions33 provided in the circumferential direction on the inner periphery of thering portion32, and includes the notches (spaces)35 formed between theprotrusions33. Thus, the induced currents generated in the etchedmember31 flow in the same direction as the flowing direction of electricity in theplasma antenna34, when viewed from thesubstrate3. Therefore, even though the etchedmember31, an electric conductor, exists below theplasma antenna34, the electromagnetic waves are reliably thrown from theplasma antenna34 into thechamber1. Consequently, the Cl₂gas plasma21 can be stably generated below the etchedmember31.
• A barrier metal film production apparatus and a barrier metal film production method according to the third embodiment of the present invention will be described with reference toFIG. 6.FIG. 6 is a schematic side view of the barrier metal film production apparatus according to the third embodiment of the present invention. The same members as the members illustrated inFIGS. 1 and 3 are assigned the same numerals, and duplicate explanations are omitted.
• The opening of an upper portion of thechamber1 is closed with aceiling board30, for example, made of a ceramic (an insulating material). An etchedmember41 made of a metal (e.g., W, Ti, Ta or TiSi) is provided on a lower surface of theceiling board30, and the etchedmember41 is of a quadrangular pyramidal shape. Slit-shaped second openingportions42 are formed at a plurality of locations (for example, four locations) in the periphery of an upper part of the cylindrical portion of thechamber1, and one end of a tubularsecond passage43 is fixed to thesecond opening portion42.
• A tubularsecond excitation chamber44 made of an insulator is provided halfway through thesecond passage43, and a coiledsecond plasma antenna45 is provided around thesecond excitation chamber44. Theplasma antenna45 is connected to amatching instrument48 and apower source49 to receive power. Thesecond plasma antenna45, the matchinginstrument48 and thepower source49 constitute plasma generation means.
• Aflow controller46 is connected to the other end of thesecond passage43, and a chlorine-containing source gas (a Cl₂gas diluted with He or Ar to a chlorine concentration of ≦50%, preferably about 10%) is supplied into thepassage43 via theflow controller46. By shooting electromagnetic waves from thesecond plasma antenna45 into thesecond excitation chamber44, the Cl₂gas is ionized to generate a Cl₂gas plasma (source gas plasma)47. Because of the generation of the Cl₂gas plasma47, excited chlorine is fed into thechamber1 through thesecond opening portion42, whereupon the etchedmember41 is etched with excited chlorine.
• With the above-described barrier metal film production apparatus, the source gas is supplied into thesecond passage43 via theflow controller46 and fed into thesecond excitation chamber44. By shooting electromagnetic waves from thesecond plasma antenna45 into thesecond excitation chamber44, the Cl₂gas is ionized to generate a Cl₂gas plasma (source gas plasma)47. Since a predetermined differential pressure has been established between the pressure inside thechamber1 and the pressure inside thesecond excitation chamber44 by thevacuum device8, the excited chlorine of the Cl₂gas plasma47 in thesecond excitation chamber44 is fed to the etchedmember41 inside thechamber1 through thesecond opening portion42. The excited chlorine causes an etching reaction to the etchedmember41, forming a precursor (M_xCl_y)22 inside thechamber1. At this time, the etchedmember41 is maintained at a predetermined temperature (e.g., 200 to 400° C.), which is higher than the temperature of thesubstrate3, by aheater50 provided in theceiling board30.
• In theexcitation chamber16, the NH₃gas is ionized to generate an NH₃gas plasma23. The excited ammonia of the NH₃gas plasma23 in theexcitation chamber16 is fed to the precursor (M_xCl_y)22 inside thechamber1 through the openingportion14. As a result, the metal component of the precursor (M_xCl_y)22 and ammonia react to form a metal nitride (MN). At this time, theexcitation chamber16 is maintained by the plasma at a predetermined temperature (e.g., 200 to 400° C.) which is higher than the temperature of thesubstrate3.
• The metal nitride (MN) formed within thechamber1 is transported toward thesubstrate3 controlled to a low temperature, whereby athin MN film24 is formed on the surface of thesubstrate3. After thethin MN film24 is formed, the supply of the NH₃gas and the supply of power to thepower source19 are cut off. Thus, the precursor (M_xCl_y)22 is transported toward thesubstrate3 controlled to a lower temperature than the temperature of the etchedmember41. The precursor (M_xCl_y)22 transported toward thesubstrate3 is converted into only metal (M) ions by a reduction reaction, and directed at thesubstrate3 to form a thin M film25 on thethin MN film24 placed on thesubstrate3. Abarrier metal film26 is composed of thethin MN film24 and the thin M film25 (seeFIG. 2). The gases and the etching products that have not been involved in the reactions are exhausted through anexhaust port27.
• With the above-described barrier metal film production apparatus, similar to the first embodiment and the second embodiment, the metal is formed by plasmas to produce thebarrier metal film26. Thus, thebarrier metal film26 can be formed uniformly to a small thickness. Consequently, thebarrier metal film26 can be formed highly accurately at a high speed with excellent burial properties in a very small thickness even to the interior of a tiny depression, for example several hundred nanometers wide, which has been provided in thesubstrate3.
• Furthermore, the Cl₂gas plasma47 is generated in thesecond excitation chamber44 isolated from thechamber1. Thus, thesubstrate3 is not exposed to the plasma any more, and thesubstrate3 becomes free from damage from the plasma.
• As the means for generating the Cl₂gas plasma47 in thesecond excitation chamber44, namely, the means for exciting the source gas to convert it into an excited source gas, it is possible to use microwaves, laser, electron rays, or synchrotron radiation. It is also permissible to form the precursor by heating the metal filament to a high temperature. The construction for isolating the Cl₂gas plasma47 from thesubstrate3 may be the provision of thesecond excitation chamber44 in thepassage43, as stated above, or may be other construction, for example, the isolation of thechamber1.
• A barrier metal film production apparatus and a barrier metal film production method according to the fourth embodiment of the present invention will be described with reference toFIG. 7.FIG. 7 is a schematic side view of a barrier metal film production apparatus according to the fourth embodiment of the present invention. The same members as the members illustrated inFIG. 1 are assigned the same numerals, and duplicate explanations are omitted.
• Compared with the barrier metal film production apparatus of the first embodiment shown inFIG. 1, theplasma antenna9 is not provided around the cylindrical portion of thechamber1, and the matchinginstrument10 andpower source11 are connected to themetal member7 for supply of power to themetal member7.
• With the above-described barrier metal film production apparatus, the source gas is supplied from thenozzle12 into thechamber1, and electromagnetic waves are shot from themetal member7 into thechamber1, whereby the Cl₂gas is ionized to generate a Cl₂gas plasma (source gas plasma)21. The Cl₂gas plasma21 causes an etching reaction to themetal member7, forming a precursor (M_xCl_y)22. At this time, themetal member7 is maintained at a temperature (e.g., 200 to 400° C.), which is higher than the temperature of thesubstrate3, by temperature control means (not shown).
• In theexcitation chamber16, the NH₃gas is ionized to generate an NH₃gas plasma23. The excited ammonia of the NH₃gas plasma23 in theexcitation chamber16 is fed to the precursor (M_xCl_y)22 inside thechamber1 through the openingportion14. As a result, the metal component of the precursor (M_xCl_y)22 and ammonia react to form a metal nitride (MN). At this time, theexcitation chamber16 is maintained by the plasma at a predetermined temperature (e.g., 200 to 400° C.) which is higher than the temperature of thesubstrate3.
• The metal nitride (MN) formed within thechamber1 is transported toward thesubstrate3 controlled to a low temperature, whereby athin MN film24 is formed on the surface of thesubstrate3. After thethin MN film24 is formed, the supply of the NH₃gas and the supply of power to thepower source19 are cut off. Thus, the precursor (M_xCl_y)22 is transported toward thesubstrate3 controlled to a lower temperature than the temperature of themetal member7. The precursor (M_xCl_y)22 transported toward thesubstrate3 is converted into only metal (M) ions by a reduction reaction, and directed at thesubstrate3 to form a thin M film25 on thethin MN film24 placed on thesubstrate3. Abarrier metal film26 is composed of thethin MN film24 and the thin M film25 (seeFIG. 2). The gases and the etching products that have not been involved in the reactions are exhausted through anexhaust port27.
• With the above-described barrier metal film production apparatus, similar to the first embodiment to the third embodiment, the metal is formed by plasmas to produce thebarrier metal film26. Thus, thebarrier metal film26 can be formed uniformly to a small thickness. Consequently, thebarrier metal film26 can be formed highly accurately at a high speed with excellent burial properties in a very small thickness even to the interior of a tiny depression, for example several hundred nanometers wide, which has been provided in thesubstrate3.
• Furthermore, themetal member7 itself is applied as an electrode for plasma generation. Thus, theplasma antenna9 need not be provided around the cylindrical portion of thechamber1, and the degree of freedom of the construction in the surroundings can be increased.
• A barrier metal film production apparatus and a barrier metal film production method according to the fifth embodiment of the present invention will be described with reference toFIG. 8.FIG. 8 is a schematic side view of the barrier metal film production apparatus according to the fifth embodiment of the present invention. The same members as the members illustrated inFIG. 1 are assigned the same numerals, and duplicate explanations are omitted.
• Compared with the first embodiment shown inFIG. 1, the barrier metal film production apparatus shown inFIG. 8 lacks the openingportion14,passage15,excitation chamber16,plasma antenna17, matchinginstrument18,power source19 and flowcontroller20.Nozzles12 for supplying a gas mixture of a source gas (Cl₂gas) and a nitrogen gas (N₂gas) as a nitrogen-containing gas to the interior of thechamber1 are connected to the cylindrical portion of thechamber1. The Cl₂gas and the N₂gas are mixed in a mixedgas flow controller81, and the gas mixture of the Cl₂gas and the N₂gas is supplied to thenozzle12 via the mixedgas flow controller81. Other constructions are the same as in the first embodiment.
• With the above-described barrier metal film production apparatus, the mixed gas comprising the Cl₂gas and the N₂gas is supplied through thenozzles12 to the interior of thechamber1, and electromagnetic waves are shot from theplasma antenna9 into thechamber1. As a result, the Cl₂gas and the N₂gas are ionized to generate a Cl₂gas/N₂gas plasma82. The Cl₂gas/N₂gas plasma82 causes an etching reaction to themetal member7, forming a precursor (M_xCl_y: M is a metal such as W, Ti, Ta or TiSi)22. Also, theprecursor22 and N₂react to form a metal nitride (MN). At this time, themetal member7 is maintained by the plasma (or temperature control means (not shown)) at a predetermined temperature (e.g., 200 to 400° C.) which is higher than the temperature of thesubstrate3.
• The metal nitride (MN) formed within thechamber1 is transported toward thesubstrate3 controlled to a low temperature, whereby athin MN film24 is formed on the surface of thesubstrate3. After thethin MN film24 is formed, the supply of the N₂gas to the mixedgas flow controller81 is cut off. Thus, the precursor (M_xCl_y)22 is transported toward thesubstrate3 controlled to a lower temperature than the temperature of themetal member7. The precursor (M_xCl_y)22 transported toward thesubstrate3 is converted into only metal (M) ions by a reduction reaction, and directed at thesubstrate3 to form a thin M film25 on the surface of thesubstrate3. Abarrier metal film26 is composed of thethin MN film24 and the thin M film25 (seeFIG. 2).
• Thesubstrate3, on which thebarrier metal film26 has been formed, is to have a thin copper (Cu) film or a thin aluminum (Al) film formed on thebarrier metal film26 by a film forming device. Because of the presence of thebarrier metal film26, there arise advantages, for example, such that thethin MN film24 eliminates diffusion of Cu into thesubstrate3, and the thin M film25 ensures adhesion of Cu.
• If the material to be formed as a film is a material unproblematic in terms of adhesion (e.g., Al), or if it is a metal to which the nitride can retain adhesion, the thin M film25 can be omitted from thebarrier metal film26.
• With the above-described barrier metal film production apparatus, the same effects as in the first embodiment are obtained. In addition, the supply line for the gases can be simplified, and the number of the plasma sources can be decreased. Thus, the cost of the product can be reduced.
• The sixth embodiment of a barrier metal film production apparatus and a barrier metal film production method according to the present invention will be described with reference toFIG. 9.FIG. 9 is a schematic side view of the barrier metal film production apparatus according to the sixth embodiment of the present invention. The same members as in the second and fifth embodiments illustrated in FIGS.3 to5 and8 are assigned the same numerals, and duplicate explanations are omitted.
• Compared with the second embodiment shown inFIG. 3, the barrier metal film production apparatus shown inFIG. 9 lacks the openingportion14,passage15,excitation chamber16,plasma antenna17, matchinginstrument18,power source19 and flowcontroller20.Nozzles12 for supplying a gas mixture of a source gas (Cl₂gas) and a nitrogen gas (N₂gas) as a nitrogen-containing gas to the interior of thechamber1 are connected to the cylindrical portion of thechamber1. The Cl₂gas and the N₂gas are mixed in a mixedgas flow controller81, and the gas mixture of the Cl₂gas and the N₂gas is supplied to thenozzle12 via the mixedgas flow controller81. Other constructions are the same as in the second embodiment.
• With the above-described barrier metal film production apparatus, the mixed gas comprising the Cl₂gas and the N₂gas is supplied through thenozzles12 to the interior of thechamber1, and electromagnetic waves are shot from theplasma antenna34 into thechamber1. As a result, the Cl₂gas and the N₂gas are ionized to generate a Cl₂gas/N₂gas plasma82. The etchedmember31, an electric conductor, is present below theplasma antenna34. As stated earlier, however, the Cl₂gas/N₂gas plasma82 occurs stably between the etchedmember31 and thesubstrate3, namely, below the etchedmember31.
• The Cl₂gas/N₂gas plasma82 causes an etching reaction to the etchedmember31, forming a precursor (M_xCl_y: M is a metal such as W, Ti, Ta or TiSi)22. Also, theprecursor22 and N₂react to form a metal nitride (MN). At this time, the etchedmember31 is maintained by the plasma (or temperature control means (not shown)) at a predetermined temperature (e.g., 200 to 400° C.) which is higher than the temperature of thesubstrate3.
• The metal nitride (MN) formed within thechamber1 is transported toward thesubstrate3 controlled to a low temperature, whereby athin MN film24 is formed on the surface of thesubstrate3. After thethin MN film24 is formed, the supply of the N₂gas to the mixedgas flow controller81 is cut off. Thus, the precursor (M_xCl_y)22 is transported toward thesubstrate3 controlled to a lower temperature than the temperature of the etchedmember31. The precursor (M_xCl_y)22 transported toward thesubstrate3 is converted into only metal (M) ions by a reduction reaction, and directed at thesubstrate3 to form a thin M film25 on thethin MN film24 on thesubstrate3. Abarrier metal film26 is composed of thethin MN film24 and the thin M film25 (seeFIG. 2).
• Thesubstrate3, on which thebarrier metal film26 has been formed, is to have a thin copper (Cu) film or a thin aluminum (Al) film formed on thebarrier metal film26 by a film forming device. Because of the presence of thebarrier metal film26, there arise advantages, for example, such that thethin MN film24 eliminates diffusion of Cu into thesubstrate3, and the thin M film25 ensures adhesion of Cu.
• If the material to be formed as a film is a material unproblematic in terms of adhesion (e.g., Al), or if it is a metal to which the nitride can retain adhesion, the thin M film25 can be omitted from thebarrier metal film26.
• With the above-described barrier metal film production apparatus, the same effects as in the second embodiment are obtained. In addition, the supply line for the gases can be simplified, and the number of the plasma sources can be decreased. Thus, the cost of the product can be reduced.
• The seventh embodiment of a barrier metal film production apparatus and a barrier metal film production method according to the present invention will be described with reference toFIG. 10.FIG. 10 is a schematic side view of the barrier metal film production apparatus according to the seventh embodiment of the present invention. The same members as in the third and fifth embodiments illustrated inFIGS. 6 and 8 are assigned the same numerals, and duplicate explanations are omitted.
• Compared with the third embodiment shown inFIG. 6, the barrier metal film production apparatus shown inFIG. 10 lacks the openingportion14,passage15,excitation chamber16,plasma antenna17, matchinginstrument18,power source19 and flowcontroller20. A gas mixture of a source gas (Cl₂gas) and a nitrogen gas (N₂gas) as a nitrogen-containing gas is supplied from a mixedgas flow controller81 to asecond excitation chamber44. Other constructions are the same as in the third embodiment.
• With the above-described barrier metal film production apparatus, the mixed gas comprising the Cl₂gas and the N₂gas is supplied into asecond passage43 via the mixedgas flow controller81, and fed into thesecond excitation chamber44. Electromagnetic waves are shot from asecond plasma antenna45 into thesecond excitation chamber44. As a result, the Cl₂gas and the N₂gas are ionized to generate a Cl₂gas/N₂gas plasma82. Since a predetermined differential pressure has been established between the pressure inside thechamber1 and the pressure inside thesecond excitation chamber44 by thevacuum device8, the excited chlorine and excited nitrogen of the Cl₂gas/N₂gas plasma82 in thesecond excitation chamber44 are fed to the etchedmember41 inside thechamber1 through thesecond opening portion42. The excited chlorine causes an etching reaction to the etchedmember41, forming a precursor (M_xCl_y)22 inside thechamber1. Also, theprecursor22 and the excited nitrogen react to form a metal nitride (MN). At this time, the etchedmember41 is maintained at a predetermined temperature (e.g., 200 to 400° C.), which is higher than the temperature of thesubstrate3, by aheater50 provided in aceiling board30.
• The metal nitride (MN) formed within thechamber1 is transported toward thesubstrate3 controlled to a low temperature, whereby athin MN film24 is formed on the surface of thesubstrate3. After thethin MN film24 is formed, the supply of the N₂gas to the mixedgas flow controller81 is cut off. Thus, the precursor (M_xCl_y)22 is transported toward thesubstrate3 controlled to a lower temperature than the temperature of the etchedmember41. The precursor (M_xCl_y)22 transported toward thesubstrate3 is converted into only metal (M) ions by a reduction reaction, and directed at thesubstrate3 to form a thin M film25 on thethin MN film24 on thesubstrate3. Abarrier metal film26 is composed of thethin MN film24 and the thin M film25 (seeFIG. 2).
• Thesubstrate3, on which thebarrier metal film26 has been formed, is to have a thin copper (Cu) film or a thin aluminum (Al) film formed on thebarrier metal film26 by a film forming device. Because of the presence of thebarrier metal film26, there arise advantages, for example, such that thethin MN film24 eliminates diffusion of Cu into thesubstrate3, and the thin M film25 ensures adhesion of Cu.
• If the material to be formed as a film is a material unproblematic in terms of adhesion (e.g., Al), or if it is a metal to which the nitride can retain adhesion, the thin M film25 can be omitted from thebarrier metal film26.
• With the above-described barrier metal film production apparatus, the same effects as in the third embodiment are obtained. In addition, the supply line for the gases can be simplified, and the number of the plasma sources can be decreased. Thus, the cost of the product can be reduced.
• The eighth embodiment of a barrier metal film production apparatus and a barrier metal film production method according to the present invention will be described with reference toFIG. 11.FIG. 11 is a schematic side view of the barrier metal film production apparatus according to the eighth embodiment of the present invention. The same members as in the fourth embodiment and the fifth embodiment illustrated inFIGS. 7 and 8 are assigned the same numerals, and duplicate explanations are omitted.
• Compared with the fourth embodiment shown inFIG. 7, the barrier metal film production apparatus shown in FIG.11 lacks the openingportion14,passage15,excitation chamber16,plasma antenna17, matchinginstrument18,power source19 and flowcontroller20.Nozzles12 for supplying a gas mixture of a source gas (Cl₂gas) and a nitrogen gas (N₂gas) as a nitrogen-containing gas to the interior of thechamber1 are connected to the cylindrical portion of thechamber1. The Cl₂gas and the N₂gas are mixed in a mixedgas flow controller81, and the gas mixture of the Cl₂gas and the N₂gas is supplied to thenozzle12 via the mixedgas flow controller81. Other constructions are the same as in the fourth embodiment.
• With the above-described barrier metal film production apparatus, the mixed gas comprising the Cl₂gas and the N₂gas is supplied through thenozzles12 to the interior of thechamber1, and electromagnetic waves are shot from themetal member7 into thechamber1. As a result, the Cl₂gas and the N₂gas are ionized to generate a Cl₂gas/N₂gas plasma82. The Cl₂gas/N₂gas plasma82 causes an etching reaction to themetal member7, forming a precursor (M_xCl_y: M is a metal such as W, Ti, Ta or TiSi)22. Also, theprecursor22 and N₂react to form a metal nitride (MN). At this time, themetal member7 is maintained by the plasma (or temperature control means (not shown)) at a predetermined temperature (e.g., 200 to 400° C.) which is higher than the temperature of thesubstrate3.
• The metal nitride (MN) formed within thechamber1 is transported toward thesubstrate3 controlled to a low temperature, whereby athin MN film24 is formed on the surface of thesubstrate3. After thethin MN film24 is formed, the supply of the N₂gas to the mixedgas flow controller81 is cut off. Thus, the precursor (M_xCl_y)22 is transported toward thesubstrate3 controlled to a lower temperature than the temperature of themetal member7. The precursor (M_xCl_y)22 transported toward thesubstrate3 is converted into only metal (M) ions by a reduction reaction, and directed at thesubstrate3 to form a thin M film25 on thethin MN film24 on thesubstrate3. Abarrier metal film26 is composed of thethin MN film24 and the thin M film25 (seeFIG. 2).
• Thesubstrate3, on which thebarrier metal film26 has been formed, is to have a thin copper (Cu) film or a thin aluminum (Al) film formed on thebarrier metal film26 by a film forming device. Because of the presence of thebarrier metal film26, there arise advantages, for example, such that thethin MN film24 eliminates diffusion of Cu into thesubstrate3, and the thin M film25 ensures adhesion of Cu.
• If the material to be formed as a film is a material unproblematic in terms of adhesion (e.g., Al), or if it is a metal to which the nitride can retain adhesion, the thin M film25 can be omitted from thebarrier metal film26.
• With the above-described barrier metal film production apparatus, the same effects as in the fourth embodiment are obtained. In addition, the supply line for the gases can be simplified, and the number of the plasma sources can be decreased. Thus, the cost of the product can be reduced.
• In the foregoing fifth to eighth embodiments, the N₂gas is mixed with the Cl₂gas in the mixedgas flow controller81, and the gas mixture is supplied into thechamber1. However, the N₂gas and the Cl₂gas can be supplied through separate nozzles. Also, ammonia can be applied as the nitrogen-containing gas.
• The ninth embodiment of the barrier metal film production apparatus and barrier metal film production method of the present invention will be described with reference toFIGS. 12 and 18.FIG. 12 is a schematic side view of the barrier metal film production apparatus according to the ninth embodiment of the present invention.FIG. 13 shows the sectional status of a substrate illustrating a barrier metal film.FIGS. 14 and 15 show the concept status of a barrier metal film in denitrification.FIG. 16 shows the concept status of a barrier metal film in oxide layer formation.FIG. 17 represents the relationship between the contact angle of copper particles and the oxygen concentration of the substrate.FIG. 18 shows the concept status of a barrier metal film in hydroxyl group formation.FIG. 19 schematically shows a construction illustrating another example of diluent gas supply means.
• As shown inFIG. 12, asupport platform102 is provided near the bottom of acylindrical chamber101 made of, say, a ceramic (an insulating material), and asubstrate103 is placed on thesupport platform102. Temperature control means106, as control means, equipped with aheater104 and refrigerant flow-throughmeans105 is provided in thesupport platform102 so that thesupport platform102 is controlled to a predetermined temperature (for example, a temperature at which thesubstrate103 is maintained at 100 to 200° C.) by the temperature control means106.
• An upper surface of thechamber101 is an opening, which is closed with ametal member107, as an etched member, made of a metal (e.g., W, Ti, Ta, or TiSi). The interior of thechamber101 closed with themetal member107 is maintained at a predetermined pressure by avacuum device108. Aplasma antenna109, as a coiled winding antenna of plasma generation means, is provided around a cylindrical portion of thechamber101. A matchinginstrument110 and apower source111 are connected to theplasma antenna109 to supply power.
• Anozzle112, as source gas supply means, for supplying a source gas (a Cl₂gas diluted with He or Ar to a chlorine concentration of ≦50%, preferably about 10%), containing chlorine as a halogen, to the interior of thechamber101 is connected to the cylindrical portion of thechamber101 below themetal member107. Thenozzle112 is fed with the source gas via aflow controller113. The source gas is supplied from thenozzle112, and electromagnetic waves are shot from theplasma antenna109 into thechamber101, whereby the Cl₂gas is ionized to generate a Cl₂gas plasma (plasma generation means). Fluorine (F), bromine (Br) or iodine (I) can also be applied as the halogen to be incorporated into the source gas.
• Anozzle114, as nitrogen-containing gas supply means, for supplying an ammonia gas (NH₃gas) as a nitrogen-containing gas, to the interior of thechamber101 is connected to the cylindrical portion of thechamber101 below themetal member107. The NH₃gas is supplied from thenozzle114, and electromagnetic waves are shot from theplasma antenna109 into thechamber101, whereby the NH₃gas is ionized to generate an NH₃gas plasma (plasma generation means).
• Adiluent gas nozzle121 is provided, as diluent gas supply means, for supplying an Ar gas as a diluent gas, to the interior of thechamber101 above the surface of thesubstrate103. The Ar gas is supplied from thediluent gas nozzle121, and electromagnetic waves are shot from theplasma antenna109 into thechamber101, whereby the Ar gas is ionized to generate an Ar gas plasma (surface treatment plasma generation means).
• As described above, the diluent gas supply means applies the Ar gas as the diluent gas for the Cl₂gas. In this case, as shown inFIG. 19, acontrol valve122 may be provided at the site of merger between the source gas (Cl₂gas) and the diluent gas (Ar gas) so that the Cl₂gas is stopped during generation of the Ar gas plasma, and only the Ar gas is supplied through thenozzle112. According to this construction, there is no need for the provision of thediluent gas nozzle121, presenting advantage in space.
• Anoxygen gas nozzle115 is provided, as oxygen gas supply means, for supplying an oxygen gas (O₂gas) to the interior of thechamber101 above the surface of thesubstrate103. The O₂gas is supplied from theoxygen gas nozzle115, and electromagnetic waves are shot from theplasma antenna109 into thechamber101, whereby the O₂gas is ionized to generate an O₂gas plasma (oxygen plasma generation means).
• Furthermore, ahydrogen gas nozzle116 is provided, as hydrogen gas supply means, for supplying a hydrogen gas (H₂gas) to the interior of thechamber101 above the surface of thesubstrate103. The H₂gas is supplied from thehydrogen gas nozzle116, and electromagnetic waves are shot from theplasma antenna109 into thechamber101, whereby the H₂gas is ionized to generate an H₂gas plasma (hydroxyl group plasma generation means).
• With the above-described barrier metal film production apparatus, the source gas is supplied through thenozzle112 to the interior of thechamber101, and electromagnetic waves are shot from theplasma antenna109 into thechamber101. As a result, the Cl₂gas is ionized to generate a Cl₂gas plasma (source gas plasma). The Cl₂gas plasma causes an etching reaction to themetal member107, forming a precursor (M_xCl_y: M is a metal such as W, Ti, Ta or TiSi)120. Themetal member107 is maintained by the plasma at a predetermined temperature (e.g., 200 to 400° C.) which is higher than the temperature of thesubstrate103.
• Also, the NH₃gas is supplied into thechamber101 through thenozzle114, and electromagnetic waves are shot from theplasma antenna109 into thechamber101. Thus, the NH₃gas is ionized to generate an NH₃gas plasma, which causes a reduction reaction with theprecursor120, forming a metal nitride (MN). The metal nitride (MN) formed within thechamber101 is transported toward thesubstrate103 controlled to a low temperature, whereupon MN is formed into a film on the surface of thesubstrate103 to produce a barrier metal film123 (seeFIG. 13).
• The reaction for formation of thebarrier metal film123 can be expressed by:
  2MCl+2NH₃→2MN↓+HCl↑+2H₂↑
• The gases and the etching products that have not been involved in the reaction are exhausted through anexhaust port117.
• After the barrier metal film1123 has been formed, the Ar gas is supplied from thediluent gas nozzle121, and electromagnetic waves are shot from theplasma antenna109 into thechamber101, thereby generating an Ar gas plasma. On the surface of thesubstrate103, thebarrier metal film123 of MN has been formed, as shown inFIG. 14. Thus, upon generation of the Ar gas plasma, Ar⁺ etches thebarrier metal film123 on the surface of thesubstrate103, thereby performing a treatment for removing the nitrogen atoms (N) of the MN in the superficial layer to decrease the nitrogen content of the superficial layer relative to the interior of the matrix of the barrier metal film123 (denitrification).
• As shown inFIG. 14, thebarrier metal film123 comprises M and N in an amorphous state. In this state, N of a lower mass is preferentially removed by Ar⁺, so that the superficial layer of the barrier metal film123 (for example, up to a half, preferably about a third, of the entire film thickness) is denitrified. As a result, there emerges thebarrier metal film123 of a two-layer structure, ametal layer123asubstantially composed of M, and anMN layer123b, as shown inFIG. 15. On this occasion, the entire film thickness of thebarrier metal film123 remains the film thickness having the single layer.
• Immediately before formation of the most superficial layer of thebarrier metal film123 is completed, a trace amount of O₂gas is supplied through theoxygen gas nozzle115 into thechamber101. At the same time, electromagnetic waves are shot from theplasma antenna109 into thechamber101 to generate an O₂gas plasma. As a result, anoxide layer124 is formed on the surface of themetal layer123acomposed substantially of M, as shown inFIG. 16. Since theoxide layer124 has been formed, if a metal (e.g., copper) is deposited (formed as a film) on the surface of thebarrier metal film123, wetting with the metal is satisfactory, thus increasing adhesion.
• In detail, it has been confirmed, as shown inFIG. 17, that the higher the oxygen concentration of thesubstrate103, the smaller the contact angle θ of a copper particle (the angle that takes minimal surface energy in the presence of a balanced surface tension when the substrate is considered to be a solid and copper is deemed to be a liquid). That is, as the oxygen concentration of thesubstrate103 increases, the copper particle adheres in a collapsed state (a state of high wetting) to the surface of thesubstrate103. Hence, the O₂gas plasma is generated to form theoxide layer124 on the surface of themetal layer123a. By so doing, the oxygen concentration of thesubstrate103 can be increased, leading to satisfactory wetting with the metal (copper) to be formed as a film.
• After formation of theoxide layer124 on the surface of themetal layer123a, the H₂gas is supplied from thehydrogen gas nozzle116 into thechamber101, and electromagnetic waves are shot from theplasma antenna109 into thechamber101, thereby generating an H₂gas plasma. As a result, hydroxyl groups (OH groups) are formed on the surface of theoxide layer124, as shown inFIG. 18. These hydroxyl groups increase hydrophilicity, and can further enhance the adhesion of the metal (copper) to be formed as a film.
• With the above-described barrier metal film production apparatus, the metal is formed by the plasma to produce thebarrier metal film123. Thus, thebarrier metal film123 can be formed uniformly to a small thickness. Consequently, thebarrier metal film123 can be formed highly accurately at a high speed with excellent burial properties in a very small thickness even to the interior of a tiny depression, for example several hundred nanometers wide, which has been provided in thesubstrate103.
• Moreover, denitrification of thebarrier metal film123 is carried out by removing the nitrogen atoms with the Ar gas plasma. Thus, thebarrier metal film123 can be granted the two-layer structure, themetal layer123asubstantially composed of M, and theMN layer123b. In addition, the entire film thickness can remain the film thickness constructed from the single layer. Thus, thebarrier metal film123 can be formed in a two-layer structure without being thickened. Of the two layers, themetal layer123acan retain adhesion to a metal to be formed as a film on the surface thereof, while the MN layer (123b) can prevent diffusion of the metal. Hence, it becomes possible to produce the barrier metal film which can be formed with good adhesion to the metal to be formed as a film, with diffusion of the metal being eliminated.
• Besides, the O₂gas plasma is generated to form theoxide layer124 on the surface of themetal layer123a. Thus, when a metal is formed as a film on the surface of thebarrier metal film123, wetting with the metal is satisfactory, and adhesion of the metal can be increased. Additionally, the H₂gas plasma is generated to form hydroxyl groups (OH groups) on the surface of theoxide layer124. Thus, the hydrophilicity improves, and can further increase the adhesion of the metal to be formed as a film.
• It is permissible to omit the step of generating the H₂gas plasma to form hydroxyl groups (OH groups) on the surface of theoxide layer124. It is also allowable to omit the step of generating the O₂gas plasma to form theoxide layer124 on the surface of themetal layer123a.
• The barrier metal film production apparatus and barrier metal film production method according to the tenth embodiment of the present invention will be described with reference toFIG. 20.FIG. 20 schematically shows the construction of the barrier metal film production apparatus according to the tenth embodiment of the present invention. The same members as the members shown inFIG. 12 are assigned the same numerals, and duplicate explanations are omitted.FIG. 21 shows the concept status of an example of production of a barrier metal film by the barrier metal film production apparatus according to the tenth embodiment of the present invention.
• Compared with the barrier metal film production apparatus of the ninth embodiment shown inFIG. 12, the barrier metal film production apparatus of the tenth embodiment shown inFIG. 20 lacks thediluent gas nozzle121. In the ninth embodiment, the Ar gas is supplied from thediluent gas nozzle121 to generate an Ar gas plasma. Using the Ar gas plasma, Ar⁺ etches thebarrier metal film123 on the surface of thesubstrate103, thereby performing a treatment for removing the nitrogen atoms (N) of the MN in the superficial layer to decrease the nitrogen content of the superficial layer relative to the interior of the matrix of the barrier metal film123 (denitrification). In the present tenth embodiment, on the other hand, when denitrification is to be performed, the O₂gas is supplied from theoxygen gas nozzle115 to generate an O₂gas plasma. O₂⁺ etches thebarrier metal film123 on the surface of thesubstrate103, performing denitrification. After denitrification, the amount of the O₂gas is decreased to form the oxide layer124 (seeFIG. 16). Other constructions and actions are the same as in the ninth embodiment.
• The tenth embodiment can decrease the number of the nozzles for supplying the gases, thus bringing advantage in space.
• In the barrier metal film production apparatus of the tenth embodiment, the O₂gas plasma can be used only for the formation of the oxide layer124 (seeFIG. 16) without being used for etching. In this case, thebarrier metal film123 is only the single layer,MN layer123b. If the metal to be formed as a film over thesubstrate103 is a metal unproblematic in terms of adhesion (such as Al), for example, the treatment for forming themetal layer123aby etching can be omitted.
• In the barrier metal film production apparatus of the tenth embodiment, moreover, the O₂gas plasma can be used similarly only for the formation of the oxide layer124 (seeFIG. 16) without being used for etching. In this case, however, after theMN layer123bis formed, the supply of the NH₃gas from thenozzle114 is cut off to terminate the reaction of theprecursor120 with an NH₃gas plasma. Then, as shown inFIG. 21, the metal component of theprecursor120 is superposed on theMN layer123b, whereby themetal layer123acan be formed.
• The reaction for formation of themetal layer123afrom the metal component of theprecursor120 can be expressed by:
  2MCl→2M↓+Cl₂↑
• The barrier metal film production apparatus and barrier metal film production method according to the eleventh embodiment of the present invention will be described with reference toFIG. 22.FIG. 22 schematically shows the construction of the barrier metal film production apparatus according to the eleventh embodiment of the present invention. The same members as in the barrier metal film production apparatus shown inFIG. 12 are assigned the same numerals, and duplicate explanations are omitted.
• As shown inFIG. 22, asupport platform102 is provided near the bottom of achamber101, and asubstrate103 is placed on thesupport platform102. Temperature control means106, as control means, equipped with aheater104 and refrigerant flow-throughmeans105 is provided in thesupport platform102 so that thesupport platform102 is controlled to a predetermined temperature (for example, a temperature at which thesubstrate103 is maintained at 100 to 200° C.) by the temperature control means106. An upper surface of thechamber101 is an opening, which is closed with a metal member107 (e.g., W, Ti, Ta, or TiSi). The interior of thechamber101 closed with themetal member107 is maintained at a predetermined pressure by avacuum device108. Aplasma antenna109 is provided around a cylindrical portion of thechamber101. A matchinginstrument110 and apower source111 are connected to theplasma antenna109 to supply power.
• Anozzle112 for supplying a source gas is connected to the cylindrical portion of thechamber101 below themetal member107. The source gas is supplied from thenozzle112, and electromagnetic waves are shot from theplasma antenna109 into thechamber101, whereby the Cl₂gas is ionized to generate a Cl₂gas plasma (plasma generation means).
• Adiluent gas nozzle121 is provided for supplying an Ar gas to the interior of thechamber101. Also, electromagnetic waves are shot from theplasma antenna109 into thechamber101. Thus, the Ar gas is ionized to generate an Ar gas plasma (surface treatment plasma generation means). If an Ar gas is applied as the diluent gas for the Cl₂gas, diluent gas supply means may be constructed, similar to the ninth embodiment, such that only the Ar gas is supplied from thenozzle112.
• Anoxygen gas nozzle115 is provided for supplying an oxygen gas (O₂gas) to the interior of thechamber101. Also, electromagnetic waves are shot from theplasma antenna109 into thechamber101. Thus, the O₂gas is ionized to generate an O₂gas plasma (oxygen plasma generation means). Moreover, ahydrogen gas nozzle116 is provided for supplying a hydrogen gas (H₂gas) to the interior of thechamber101. Also, electromagnetic waves are shot from theplasma antenna109 into thechamber101. Thus, the H₂gas is ionized to generate an H₂gas plasma (hydroxyl group plasma generation means).
• Slit-shapedopening portions131 are formed at a plurality of locations (for example, four locations; only one of the locations is shown in the drawing) in the periphery of a lower part of the cylindrical portion of thechamber101, and one end of atubular passage132 is fixed to theopening portion131. Atubular excitation chamber33 made of an insulator is provided halfway through thepassage132, and acoiled plasma antenna134 is provided around theexcitation chamber133. Theplasma antenna134 is connected to amatching instrument135 and apower source136 to receive power. Theplasma antenna134, the matchinginstrument135 and thepower source136 constitute excitation means. Aflow controller137 is connected to the other end of thepassage132, and an ammonia gas (NH₃gas) as a nitrogen-containing gas is supplied into thepassage132 via theflow controller137.
• Separately, the NH₃gas is supplied into thepassage132 via theflow controller137 and fed into theexcitation chamber133. By shooting electromagnetic waves from theplasma antenna134 into theexcitation chamber133, the NH₃gas is ionized to generate an NH₃gas plasma138. Since a predetermined differential pressure has been established between the pressure inside thechamber101 and the pressure inside theexcitation chamber133 by thevacuum device108, the excited ammonia of the NH₃gas plasma138 in theexcitation chamber133 is fed to the precursor (M_xCl_y)120 inside thechamber101 through theopening portion131.
• That is, excitation means for exciting the nitrogen-containing gas in theexcitation chamber133 isolated from thechamber101 is constructed. Because of this construction, the metal component of the precursor (M_xCl_y)120 and ammonia react to form a metal nitride (MN) (formation means). At this time, themetal member107 and theexcitation chamber133 are maintained by the plasmas at predetermined temperatures (e.g., 200 to 400° C.) which are higher than the temperature of thesubstrate103.
• With the above-described barrier metal film production apparatus, the source gas is supplied through thenozzle112 to the interior of thechamber101, and electromagnetic waves are shot from theplasma antenna109 into thechamber101. As a result, a Cl₂gas plasma (source gas plasma) occurs. The Cl₂gas plasma causes an etching reaction to themetal member107, forming a precursor (M_xCl_y)120. Themetal member107 is maintained by the plasma at a predetermined temperature (e.g., 200 to 400° C.) which is higher than the temperature of thesubstrate103.
• The excited ammonia of the NH₃gas plasma138 in theexcitation chamber133 is fed to the precursor (M_xCl_y)120 inside thechamber101 through theopening portion131. Thus, a metal nitride (MN) is formed inside thechamber101. The resulting metal nitride (MN) is transported toward thesubstrate103 controlled to a low temperature, whereby abarrier metal film23 is formed on the surface of thesubstrate103. The gases and the etching products, which have not been involved in the reaction, are exhausted through anexhaust port117.
• After thebarrier metal film123 is formed, the Ar gas is supplied from thediluent gas nozzle121, and electromagnetic waves are shot from theplasma antenna109 into thechamber101 to generate an Ar gas plasma. Using the Ar gas plasma, Ar⁺ etches thebarrier metal film123 on the surface of thesubstrate103, thereby performing a treatment for removing the nitrogen atoms (N) of the MN in the superficial layer to decrease the nitrogen content of the superficial layer relative to the interior of the matrix of the barrier metal film123 (denitrification). As a result, there emerges thebarrier metal film123 of a two-layer structure, ametal layer123asubstantially composed of M, and anMN layer123b(seeFIG. 15).
• Immediately before formation of the most superficial layer of thebarrier metal film123 is completed, a trace amount of O₂gas is supplied through theoxygen gas nozzle115 into thechamber101. At the same time, electromagnetic waves are shot from theplasma antenna109 into thechamber101 to generate an O₂gas plasma. As a result, anoxide layer124 is formed on the surface of themetal layer123acomposed substantially of M (seeFIG. 16). Since theoxide layer124 has been formed, if a metal (e.g., copper) is deposited (formed as a film) on the surface of thebarrier metal film123, wetting with the metal is satisfactory, thus increasing adhesion.
• After formation of theoxide layer124 on the surface of themetal layer123a, the H₂gas is supplied from thehydrogen gas nozzle116 into thechamber101, and electromagnetic waves are shot from theplasma antenna109 into thechamber101, thereby generating an H₂gas plasma. As a result, hydroxyl groups (OH groups) are formed on the surface of the oxide layer124 (seeFIG. 18). These hydroxyl groups increase hydrophilicity, and can further enhance the adhesion of the metal (copper) to be formed as a film.
• With the above-described barrier metal film production apparatus, thebarrier metal film123 can be formed at a high speed with excellent burial properties in a very small thickness, as in the ninth embodiment. In addition, the entire film thickness can remain the film thickness constructed from the single layer. In this state, it becomes possible to produce the barrier metal film which can be formed with good adhesion to the metal to be formed as a film, with diffusion of the metal being eliminated.
• Besides, when a metal is formed as a film on the surface of thebarrier metal film123, wetting with the metal is satisfactory, and adhesion of the metal can be increased. Additionally, the hydrophilicity improves, and can further increase the adhesion of the metal to be formed as a film.
• Further, the NH₃gas plasma138 is generated in theexcitation chamber133 isolated from thechamber101. Thus, the influence of the NH₃gas plasma138 is not exerted on the surface of thesubstrate103.
• It is permissible to omit the step of generating the H₂gas plasma to form hydroxyl groups (OH groups) on the surface of theoxide layer124. It is also allowable to omit the step of generating the O₂gas plasma to form theoxide layer124 on the surface of themetal layer123a.
• The barrier metal film production apparatus according to the eleventh embodiment shown inFIG. 22 may have a construction in which thediluent gas nozzle121 is not provided. In the eleventh embodiment, the Ar gas is supplied from thediluent gas nozzle121 to generate an Ar gas plasma. Ar⁺ etches thebarrier metal film123 on the surface of thesubstrate103, thereby removing the nitrogen atoms (N) of the MN in the superficial layer to decrease the nitrogen content of the superficial layer relative to the interior of the matrix of the barrier metal film123 (denitrification). When denitrification is to be performed, the O₂gas is supplied from theoxygen gas nozzle115 to generate an O₂gas plasma, and O₂⁺ etches thebarrier metal film123 on the surface of thesubstrate103, thereby carrying out denitrification. After denitrification, the amount of the O₂gas is decreased to form the oxide layer124 (seeFIG. 16).
• In this case, the number of the nozzles for supplying the gases can be decreased, thus bringing advantage in space.
• The O₂gas plasma can be used only for the formation of the oxide layer124 (seeFIG. 16) without being used for etching. In this case, thebarrier metal film123 is only the single layer,MN layer123b. If the metal to be formed as a film over thesubstrate103 is a metal unproblematic in terms of adhesion (such as Al), for example, the treatment for forming themetal layer123aby etching can be omitted.
• Moreover, the O₂gas plasma can be used similarly only for the formation of the oxide layer124 (seeFIG. 16) without being used for etching. After theMN layer123bis formed, the supply of the NH₃gas and the supply of power to thepower source136 may be cut off. As a result, the precursor (M_xCl_y)120 is transported toward thesubstrate103 controlled to a lower temperature than the temperature of themetal member107. The precursor (M_xCl_y)120 transported toward thesubstrate103 is converted into only metal (M) ions by a reduction reaction, and directed at thesubstrate3. Thus, themetal layer123ais superposed on theMN layer123bof thesubstrate103. In this manner, themetal layer123acan be formed (seeFIG. 21).
• A barrier metal film production apparatus and a barrier metal film production method according to a twelfth embodiment of the present invention will be described with reference to FIGS.23 to25.FIG. 23 is a schematic side view of the barrier metal film production apparatus according to the twelfth embodiment of the present invention.FIG. 24 is a view taken along the arrowed line XIII-XIII ofFIG. 23.FIG. 25 is a view taken along the arrowed line XIV-XIV ofFIG. 24. The same members as the members illustrated in FIGS.12 to22 are assigned the same numerals, and duplicate explanations are omitted.
• An upper surface of thechamber101 is an opening, which is closed with a disk-shapedceiling board141 made of an insulating material (for example, a ceramic). Anetched member142 made of a metal (e.g., W, Ti, Ta or TiSi) is interposed between the opening at the upper surface of thechamber101 and theceiling board141. The etchedmember142 is provided with aring portion143 fitted to the opening at the upper surface of thechamber101. A plurality of (12 in the illustrated embodiment)protrusions144, which extend close to the center in the diametrical direction of thechamber101 and have the same width, are provided in the circumferential direction on the inner periphery of thering portion143.
• Theprotrusions144 are integrally or removably attached to thering portion143. Notches (spaces)145 formed between theprotrusions144 are present between theceiling board141 and the interior of thechamber101. Thering portion143 is earthed, and theplural protrusions144 are electrically connected together and maintained at the same potential. Temperature control means (not shown), such as a heater, is provided in the etchedmember142 to control the temperature of the etchedmember142 to 200 to 400° C., for example.
• Second protrusions shorter in the diametrical direction than theprotrusions144 can be arranged between theprotrusions144. Moreover, short protrusions can be arranged between theprotrusion144 and the second protrusion. By so doing, the area of the etched member, an object to be etched, can be secured, with an induced current being suppressed.
• A planar winding-shapedplasma antenna146, for converting the atmosphere inside thechamber101 into a plasma, is provided above theceiling board141. Theplasma antenna146 is formed in a planar ring shape parallel to the surface of theceiling board141. A matchinginstrument110 and apower source111 are connected to theplasma antenna146 to supply power. The etchedmember142 has the plurality ofprotrusions144 provided in the circumferential direction on the inner periphery of thering portion143, and includes the notches (spaces)145 formed between theprotrusions144. Thus, theprotrusions144 are arranged between thesubstrate103 and theceiling board141 in a discontinuous state relative to the flowing direction of electricity in theplasma antenna146.
• At a cylindrical portion of thechamber101, there are provided anozzle112 for supplying a source gas into thechamber101, anozzle114 for supplying an NH₃gas into thechamber101, adiluent gas nozzle121 for supplying an Ar gas into thechamber101, anoxygen gas nozzle115 for supplying an O₂gas into thechamber101, and ahydrogen gas nozzle116 for supplying an H₂gas into thechamber101.
• With the above-described barrier metal film production apparatus, the source gas is supplied through thenozzles112 to the interior of thechamber101, and electromagnetic waves are shot from theplasma antenna146 into thechamber101. As a result, the Cl₂gas is ionized to generate a Cl₂gas plasma (source gas plasma). The etchedmember142, an electric conductor, is present below theplasma antenna146. However, the Cl₂gas plasma occurs stably between theetched member142 and thesubstrate103, namely, below the etchedmember142, under the following action:
• The action by which the Cl₂gas plasma is generated below the etchedmember142 will be described. As shown inFIG. 25, a flow A of electricity in theplasma antenna146 of the planar ring shape crosses theprotrusions144. At this time, an induced current B occurs on the surface of theprotrusion144 opposed to theplasma antenna146. Since the notches (spaces)145 are present in the etchedmember142, the induced current B flows onto the lower surface of eachprotrusion144, forming a flow a in the same direction as the flow A of electricity in the plasma antenna146 (Faraday shield).
• When the etchedmember142 is viewed from thesubstrate103, therefore, there is no flow in a direction in which the flow A of electricity in theplasma antenna146 is canceled out. Furthermore, thering portion143 is earthed, and theprotrusions144 are maintained at the same potential. Thus, even though the etchedmember142, an electric conductor, exists, the electromagnetic wave is reliably thrown from theplasma antenna146 into thechamber101. Consequently, the Cl₂gas plasma is stably generated below the etchedmember142.
• The Cl₂gas plasma causes an etching reaction to the etchedmember142, forming a precursor (M_xCl_y: M is a metal such as W, Ti, Ta or TiSi)120.
• Separately, the NH₃gas is supplied into thechamber101 through thenozzle114, and electromagnetic waves are shot from theplasma antenna146 into thechamber110. Thus, the NH₃gas is ionized to generate an NH₃gas plasma, which causes a reduction reaction with theprecursor120, forming a metal nitride (MN). The metal nitride (MN) formed within thechamber101 is transported toward thesubstrate103 controlled to a low temperature, whereupon MN is formed into a film on the surface of thesubstrate103 to produce a barrier metal film123 (seeFIG. 13).
• After thebarrier metal film123 has been formed, the Ar gas is supplied from thediluent gas nozzle121, and electromagnetic waves are shot from theplasma antenna146 into thechamber101, thereby generating an Ar gas plasma. Generation of the Ar gas plasma results in the etching of thebarrier metal film123 on the surface of thesubstrate103, thereby performing denitrification, a treatment for removing the nitrogen atoms (N) of the MN in the superficial layer of thebarrier metal film123 to decrease the nitrogen content of the superficial layer relative to the interior of the matrix of thebarrier metal film123.
• Immediately before formation of the most superficial layer of thebarrier metal film123 is completed, a trace amount of O₂gas is supplied through theoxygen gas nozzle115 into thechamber101. At the same time, electromagnetic waves are shot from theplasma antenna146 into thechamber101 to generate an O₂gas plasma. As a result, an oxide layer124 (seeFIG. 16) is formed on the surface of themetal layer123acomposed substantially of M (seeFIG. 16). Since theoxide layer124 has been formed, if a metal (e.g., copper) is deposited (formed as a film) on the surface of thebarrier metal film123, wetting with the metal is satisfactory, thus increasing adhesion.
• After formation of the oxide layer124 (seeFIG. 16) on the surface of themetal layer123a(FIG. 16), the H₂gas is supplied from thehydrogen gas nozzle116 into thechamber101, and electromagnetic waves are shot from theplasma antenna146 into thechamber101, thereby generating an H₂gas plasma. As a result, hydroxyl groups (OH groups) are formed on the surface of the oxide layer124 (seeFIG. 18). These hydroxyl groups increase hydrophilicity, and can further enhance the adhesion of the metal (copper) to be formed as a film.
• It is permissible to omit the step of generating the H₂gas plasma to form hydroxyl groups (OH groups) on the surface of the oxide layer124 (seeFIG. 18). It is also allowable to omit the step of generating the O₂gas plasma to form the oxide layer124 (FIG. 16) on the surface of themetal layer123a(FIG. 16). Furthermore, it is possible to superpose themetal layer123a, forming thebarrier metal film123. It is also possible to form thebarrier metal film123 free from themetal layer123a.
• Beside, the same nozzle construction as in the tenth embodiment (seeFIG. 20) omitting thediluent gas nozzle121 may be adopted in a configuration for formation of theprecursor120 with the exception of the etchedmember142 and theplasma antenna146. Moreover, the same construction as in the eleventh embodiment (seeFIG. 22) having theexcitation chamber133, etc. instead of thenozzle114 may be adopted in a configuration excepting the etchedmember142 and the plasma-antenna146.
• With the above-described barrier metal film production apparatus, thebarrier metal film123 can be formed uniformly to a small thickness. Consequently, thebarrier metal film123 can be formed highly accurately at a high speed with excellent burial properties in a very small thickness even to the interior of a tiny depression, for example several hundred nanometers wide, which has been provided in thesubstrate103.
• In addition, the etchedmember142 has the plurality ofprotrusions144 provided in the circumferential direction on the inner periphery of thering portion143, and includes the notches (spaces)145 formed between theprotrusions144. Thus, the induced currents generated in the etchedmember142 flow in the same direction as the flowing direction of electricity in theplasma antenna146, when viewed from thesubstrate103. Therefore, even though the etchedmember142, an electric conductor, exists below theplasma antenna146, the electromagnetic waves are reliably thrown from theplasma antenna146 into thechamber101. Consequently, the Cl₂gas plasma can be stably generated below the etchedmember142.
• A barrier metal film production apparatus and a barrier metal film production method according to the thirteenth embodiment of the present invention will be described with reference toFIG. 26.FIG. 26 is a schematic side view of a barrier metal film production apparatus according to the third embodiment of the present invention. The same members as the members illustrated in FIGS.12 to25 are assigned the same numerals, and duplicate explanations are omitted.
• The opening of an upper portion of achamber101 is closed with aceiling board141. Anetched member148 made of a metal (e.g., W, Ti, Ta or TiSi) is provided on a lower surface of theceiling board141, and the etchedmember148 is of a quadrangular pyramidal shape. Slit-shapedopening portions151 are formed at a plurality of locations (for example, four locations; one of the locations is shown in the drawing) in the periphery of an upper part of the cylindrical portion of thechamber101, and one end of atubular passage152 is fixed to theopening portion151. Atubular excitation chamber153 made of an insulator is provided halfway through thepassage152, and acoiled plasma antenna154 is provided around theexcitation chamber153. Theplasma antenna154 is connected to amatching instrument157 and apower source158 to receive power.
• Aflow controller155 is connected to the other end of thepassage152, and a chlorine-containing source gas (a Cl₂gas diluted with He or Ar to a chlorine concentration of ≦50%, preferably about 10%) is supplied into thepassage152 via theflow controller155. By shooting electromagnetic waves from theplasma antenna154 into theexcitation chamber153, the Cl₂gas is ionized to generate a Cl₂gas plasma (source gas plasma)156. Because of the generation of the Cl₂gas plasma156, excited chlorine is fed into thechamber101 through theopening portion151, whereupon the etchedmember148 is etched with excited chlorine.
• At a cylindrical portion of thechamber101, there are provided anozzle114 for supplying an NH₃gas into thechamber101, adiluent gas nozzle121 for supplying an Ar gas into thechamber101, anoxygen gas nozzle115 for supplying an O₂gas into thechamber101, and ahydrogen gas nozzle116 for supplying an H₂gas into thechamber101. Around thechamber101, aplasma antenna109, amatching instrument110 and apower source111 are provided to generate an NH₃gas plasma, an Ar gas plasma, an O₂gas plasma, and an H₂gas plasma.
• With the above-described barrier metal film production apparatus, the source gas is supplied into thepassage152 via theflow controller155 and fed into theexcitation chamber153. By shooting electromagnetic waves from theplasma antenna154 into theexcitation chamber153, the Cl₂gas is ionized to generate a Cl₂gas plasma (source gas plasma)156. Since a predetermined differential pressure has been established between the pressure inside thechamber101 and the pressure inside theexcitation chamber153 by thevacuum device108, the excited chlorine of the Cl₂gas plasma156 in theexcitation chamber153 is fed to the etchedmember148 inside thechamber101 through theopening portion151. The excited chlorine causes an etching reaction to the etchedmember148, forming aprecursor120 inside thechamber101. At this time, the etchedmember148 is maintained at a predetermined temperature (e.g., 200 to 400° C.), which is higher than the temperature of thesubstrate103, by aheater150 provided in theceiling board141.
• Separately, the NH₃gas is supplied into thechamber101 through thenozzle114, and electromagnetic waves were shot from theplasma antenna109 in to thechamber110. Thus, the NH₃gas is ionized to generate an NH₃gas plasma, which causes a reduction reaction with theprecursor120, forming a metal nitride (MN). The metal nitride (MN) formed within thechamber101 is transported toward thesubstrate103 controlled to a low temperature, whereupon MN is formed into a film on the surface of thesubstrate103 to produce a barrier metal film123 (seeFIG. 13).
• After thebarrier metal film123 has been formed, the Ar gas is supplied from thediluent gas nozzle121, and electromagnetic waves are shot from theplasma antenna109 into thechamber101, thereby generating an Ar gas plasma. Generation of the Ar gas plasma results in the etching of thebarrier metal film123 on the surface of thesubstrate103, thereby performing denitrification, a treatment for removing the nitrogen atoms (N) of the MN in the superficial layer of thebarrier metal film123 to decrease the nitrogen content of the superficial layer relative to the interior of the matrix of thebarrier metal film123.
• Immediately before formation of the most superficial layer of thebarrier metal film123 is completed, a trace amount of O₂gas is supplied through theoxygen gas nozzle115 into thechamber101. At the same time, electromagnetic waves are shot from theplasma antenna109 into thechamber101 to generate an O₂gas plasma. As a result, an oxide layer124 (seeFIG. 16) is formed on the surface of themetal layer123acomposed substantially of M (seeFIG. 16). Since theoxide layer124 has been formed, if a metal (e.g., copper) is deposited (formed as a film) on the surface of thebarrier metal film123, wetting with the metal is satisfactory, thus increasing adhesion.
• After formation of the oxide layer124 (seeFIG. 16) on the surface of themetal layer123a(FIG. 16), the H₂gas is supplied from thehydrogen gas nozzle116 into thechamber101, and electromagnetic waves are shot from theplasma antenna109 into thechamber101, thereby generating an H₂gas plasma. As a result, hydroxyl groups (OH groups) are formed on the surface of the oxide layer124 (seeFIG. 18). These hydroxyl groups increase hydrophilicity, and can further enhance the adhesion of the metal (copper) to be formed as a film.
• It is permissible to omit the step of generating the H₂gas plasma to form hydroxyl groups (OH groups) on the surface of the oxide layer124 (seeFIG. 18). It is also allowable to omit the step of generating the O₂gas plasma to form the oxide layer124 (FIG. 16) on the surface of themetal layer123a(FIG. 16). Furthermore, it is possible to superpose themetal layer123a, forming thebarrier metal film123. It is also possible to form thebarrier metal film123 free from themetal layer123a.
• Beside, the same nozzle construction as in the tenth embodiment (seeFIG. 20) omitting thediluent gas nozzle121 may be adopted in a configuration for formation of theprecursor120 with the exception of the etchedmember148, openingportion151,passage152,excitation chamber153,plasma antenna154,flow controller155, matchinginstrument157, andpower source158. Moreover, the same construction as in the eleventh embodiment (seeFIG. 22) having theexcitation chamber133, etc. instead of thenozzle114 may be adopted in other configuration for formation of theprecursor120.
• With the above-described barrier metal film production apparatus, thebarrier metal film123 can be formed uniformly to a small thickness. Consequently, thebarrier metal film123 can be formed highly accurately at a high speed with excellent burial properties in a very small thickness even to the interior of a tiny depression, for example several hundred nanometers wide, which has been provided in thesubstrate103.
• Furthermore, the Cl₂gas plasma156 is generated in theexcitation chamber153 isolated from thechamber101. Thus, thesubstrate103 is not exposed to the Cl₂gas plasma156 any more, and thesubstrate103 becomes free from damage from the Cl₂gas plasma156.
• As the means for generating the Cl₂gas plasma156 in theexcitation chamber153, namely, the means for exciting the source gas to convert it into an excited source gas, it is possible to use microwaves, laser, electron rays, or synchrotron radiation. It is also permissible to form the precursor by heating the metal filament to a high temperature. The construction for isolating the Cl₂gas plasma156 from thesubstrate103 may be the provision of theexcitation chamber153 in thepassage152, or may be other construction, for example, the isolation of thechamber101.
• A barrier metal film production apparatus and a barrier metal film production method according to the fourteenth embodiment of the present invention will be described with reference toFIG. 27.FIG. 27 is a schematic side view of the barrier metal film production apparatus according to the fourteenth embodiment of the present invention. The same members as the members illustrated in FIGS.12 to26 are assigned the same numerals, and duplicate explanations are omitted.
• In the barrier metal film production apparatus according to the fourteenth embodiment, unlike the barrier metal film production apparatus according to the ninth embodiment shown inFIG. 12, theplasma antenna9 is not provided around the cylindrical portion of thechamber101, but ametal member107 is connected to amatching instrument110 and apower source111 to receive power.
• At the cylindrical portion of thechamber101, there are provided anozzle114 for supplying an NH₃gas into thechamber101, adiluent gas nozzle121 for supplying an Ar gas into thechamber101, anoxygen gas nozzle115 for supplying an O₂gas into thechamber101, and ahydrogen gas nozzle116 for supplying an H₂gas into thechamber101. By supplying power to themetal member107, an NH₃gas plasma, an Ar gas plasma, an O₂gas plasma, and an H₂gas plasma are generated. To generate the NH₃gas plasma, Ar gas plasma, O₂gas plasma, and H₂gas plasma, a coiled plasma antenna may be provided separately on the cylindrical portion of thechamber101, and the plasma antenna may be connected to a power source via a matching instrument.
• With the above-described barrier metal film production apparatus, the source gas is supplied from thenozzle112 into thechamber101, and electromagnetic waves are shot from themetal member107 into thechamber101, whereby the Cl₂gas is ionized to generate a Cl₂gas plasma (source gas plasma). The Cl₂gas plasma causes an etching reaction to themetal member107, producing a precursor (M_xCl_y)120. At this time, themetal member107 is maintained at a predetermined temperature (e.g., 200 to 400° C.), which is higher than the temperature of thesubstrate103, by temperature control means (not shown).
• Separately, the NH₃gas is supplied into thechamber101 through thenozzle114, and electromagnetic waves are shot from themetal member107 into thechamber101. Thus, the NH₃gas is ionized to generate an NH₃gas plasma, which causes a reduction reaction with theprecursor120, forming a metal nitride (MN). The metal nitride (MN) formed within thechamber101 is transported toward thesubstrate103 controlled to a low temperature, whereupon MN is formed into a film on the surface of thesubstrate103 to produce a barrier metal film123 (seeFIG. 13).
• After thebarrier metal film123 has been formed, the Ar gas is supplied from thediluent gas nozzle121, and electromagnetic waves are shot from themetal member107 into thechamber101, thereby generating an Ar gas plasma. Generation of the Ar gas plasma results in the etching of thebarrier metal film123 on the surface of thesubstrate103, thereby performing denitrification, a treatment for removing the nitrogen atoms (N) of the MN in the superficial layer of thebarrier metal film123 to decrease the nitrogen content of the superficial layer relative to the interior of the matrix of thebarrier metal film123.
• Immediately before formation of the most superficial layer of thebarrier metal film123 is completed, a trace amount of O₂gas is supplied through theoxygen gas nozzle115 into thechamber101. At the same time, electromagnetic waves are shot from themetal member107 into thechamber101 to generate an O₂gas plasma. As a result, an oxide layer124 (seeFIG. 16) is formed on the surface of ametal layer123acomposed substantially of M (seeFIG. 16). Since theoxide layer124 has been formed, if a metal (e.g., copper) is deposited (formed as a film) on the surface of thebarrier metal film123, wetting with the metal is satisfactory, thus increasing adhesion.
• After formation of the oxide layer124 (seeFIG. 16) on the surface of themetal layer123a(FIG. 16), the H₂gas is supplied from thehydrogen gas nozzle116 into thechamber101, and electromagnetic waves are shot from themetal member107 into thechamber101, thereby generating an H₂gas plasma. As a result, hydroxyl groups (OH groups) are formed on the surface of the oxide layer124 (seeFIG. 18). These hydroxyl groups increase hydrophilicity, and can further enhance the adhesion of the metal (copper) to be formed as a film.
• It is permissible to omit the step of generating the H₂gas plasma to form hydroxyl groups (OH groups) on the surface of the oxide layer124 (seeFIG. 18). It is also allowable to omit the step of generating the O₂gas plasma to form the oxide layer124 (FIG. 16) on the surface of themetal layer123a(FIG. 16). Furthermore, it is possible to superpose themetal layer123a, forming thebarrier metal film123. It is also possible to form thebarrier metal film123 free from themetal layer123a.
• Beside, the same nozzle construction as in the tenth embodiment (seeFIG. 20) omitting thediluent gas nozzle121 may be adopted in the configuration for formation of theprecursor120 with the exception of themetal member107, matchinginstrument110, andpower source111. Moreover, the same construction as in the eleventh embodiment (seeFIG. 22) having theexcitation chamber133, etc. instead of thenozzle114 may be adopted in other configuration for formation of theprecursor120.
• With the above-described barrier metal film production apparatus, thebarrier metal film123 can be formed uniformly to a small thickness. Consequently, thebarrier metal film123 can be formed highly accurately at a high speed with excellent burial properties in a very small thickness even to the interior of a tiny depression, for example several hundred nanometers wide, which has been provided in thesubstrate103.
• Furthermore, themetal member107 itself is applied as an electrode for plasma generation. Thus, there is no need for a plasma antenna around the cylindrical portion of thechamber101, and the degree of freedom of the surrounding construction can be increased.
• A metal film production method and a metal film production apparatus according to the present invention will be described with reference to the accompanying drawings. The metal film production method of the present invention involves a treatment for enhancing adhesion to a barrier metal layer of, for example, tantalum nitride (TaN) formed on the surface of a substrate in order to prevent diffusion into the substrate.
• According to a first aspect of the present invention, the barrier metal film of TaN is flattened by etching its surface with a diluent gas (e.g., argon: Ar) plasma. Further, the nitrogen atoms in the superficial layer of the barrier metal film are removed using Ar⁺, thereby decreasing the nitrogen content of the superficial layer relative to the interior of the matrix of the barrier metal film (this surface treatment will be referred to hereinafter as denitrification). The denitrification brings a state in which a film of a metal (Ta) is substantially formed in the superficial layer of the single-layer barrier metal film. In this manner, a barrier metal film is produced highly efficiently and reliably in a thin film condition, by use of an inexpensive gas having a high mass number, with the diffusion of the metal being prevented and the adhesion to the metal being maintained.
• Depending on the material for the barrier metal film, it is possible to perform only the treatment for flattening the surface by etching it with the diluent gas (e.g., argon: Ar) plasma while controlling the power of the plasma and the energization time. By so doing, adhesion can be improved. As the barrier metal film, not only TaN, but tungsten nitride or titanium nitride can be applied. As the diluent gas, not only Ar, but helium, krypton, or neon can be applied.
• The concrete construction of the apparatus according to the first aspect may be as follows: A source gas containing a halogen (e.g., a chlorine-containing gas) is supplied to the interior of a chamber between a substrate and an etched member made of Ta, and an atmosphere within the chamber is converted into a plasma to generate a chlorine gas plasma. The etched member is etched with the chlorine gas plasma to form a precursor comprising the Ta component contained in the etched member and the chlorine gas. Also, a nitrogen-containing gas is excited, and TaN, a metal nitride, is formed upon reaction between the excited nitrogen and the precursor. The resulting TaN is formed as a film on the substrate kept at a low temperature to form a barrier metal film. This process is performed using a barrier metal film production apparatus. After the barrier metal film is produced in this manner, an Ar gas plasma is generated within the chamber to carry out etching and denitrification.
• Alternatively, the concrete apparatus construction of the first aspect may be as follows: A chlorine gas is supplied into a chamber, and an atmosphere within the chamber is converted into a plasma to generate a chlorine gas plasma. An etched member made of copper (Cu) is etched with the chlorine gas plasma to form a precursor comprising the Cu component contained in the etched member and chlorine inside the chamber. The temperature of the substrate is rendered lower than the temperature of the etched member to form a film of the Cu component of the precursor on the substrate. This process is performed by use of a metal film production apparatus. Before the substrate having the barrier metal film of TaN formed thereon is housed in the chamber and the Cu component is formed as a film thereon, the Ar gas plasma is generated to carry out etching and denitrification.
• FIG. 28 shows an outline of an apparatus for a film formation process for forming a Cu film. As shown, for example, inFIG. 28, a handlingrobot401 for transporting a substrate is installed at a central site. Around therobot401, there are provided anaccommodation device402 for accommodating the substrate, abarrier metal CVD403 for forming a barrier metal film on the substrate, and a Cu-CVD404 for forming a Cu film. Therobot401 transports the substrate from theaccommodation device402 to thebarrier metal CVD403, from thebarrier metal CVD403 to the Cu-CVD404, and from the Cu-CVD404 to theaccommodation device402. With such an apparatus for the film formation process, the metal film production apparatus according to the first aspect is provided in the Cu-CVD404.
• The metal film production apparatus in the first aspect may be provided in thebarrier metal CVD403, or a dedicated metal film production apparatus according to the first aspect may be provided around therobot401.
• Embodiments of the metal film production method and metal film production apparatus according to the first aspect will be described with reference to the accompanying drawings, with the provision of the apparatus in the Cu-CVD404 being taken as an example.
• FIG. 29 is a schematic side view of a metal film production apparatus according to the fifteenth embodiment of the present invention.FIG. 30 is a schematic construction drawing showing another example of diluent gas supply means.FIG. 31 shows the sectional status of a substrate illustrating a barrier metal film.FIGS. 32 and 33 show the concept status of a barrier metal film in denitrification. The illustrated metal film production apparatus corresponds to the Cu-CVD404 shown inFIG. 1.
• As shown inFIG. 29, asupport platform202 is provided near the bottom of acylindrical chamber201 made of, say, a ceramic (an insulating material), and asubstrate203 is placed on thesupport platform202. Temperature control means206, as control means, equipped with aheater204 and refrigerant flow-throughmeans205 is provided in thesupport platform202 so that thesupport platform202 is controlled to a predetermined temperature (for example, a temperature at which thesubstrate203 is maintained at 100 to 200° C.) by the temperature control means206.
• An upper surface of thechamber201 is an opening, which is closed with acopper plate member207, as an etched member, made of a metal. The interior of thechamber201 closed with thecopper plate member207 is maintained at a predetermined pressure by avacuum device208. Acoiled plasma antenna209 is provided around a cylindrical portion of thechamber201. A matchinginstrument210 and apower source211 are connected to theplasma antenna209 to supply power. Plasma generation means is constituted by theplasma antenna209, matchinginstrument210 andpower source211.
• Nozzles212 for supplying a source gas (a Cl₂gas diluted with He or Ar to a chlorine concentration of ≦50%, preferably about 10%), containing chlorine as a halogen, to the interior of thechamber201 are connected to the cylindrical portion of thechamber201 above thesupport platform202. Thenozzle212 is fed with the source gas via aflow controller213. Within thechamber201, the source gas is fed toward the copper plate member207 (source gas supply means). Fluorine (F), bromine (Br) or iodine (I) can also be applied as the halogen to be incorporated into the source gas.
• With the above-described metal film production apparatus, the source gas is supplied from thenozzles212 into thechamber201, and electromagnetic waves are shot from theplasma antenna209 into thechamber201, whereby the Cl₂gas is ionized to generate a Cl₂gas plasma (source gas plasma)214. The pressure inside thechamber201, set by thevacuum device208, is such a high pressure that the plasma density of the Cl₂gas plasma214 will be higher toward the wall surface within thechamber201. As means for increasing the plasma density of the Cl₂gas plasma214 on the wall surface side, the frequency of thepower source211 may be increased.
• The Cl₂gas plasma214 causes an etching reaction to thecopper plate member207, forming a precursor (Cu_xCl_y)215. At this time, thecopper plate member207 is maintained by the Cl₂gas plasma214 at a predetermined temperature (e.g., 200 to 400° C.) which is higher than the temperature of thesubstrate203.
• The precursor (Cu_xCl_y)215 formed within thechamber201 is transported toward thesubstrate203 controlled to a lower temperature than the temperature of thecopper plate member207. The precursor (Cu_xCl_y)215 transported toward thesubstrate203 is converted into only Cu ions by a reduction reaction, and directed at thesubstrate203 to form athin Cu film216 on the surface of thesubstrate203.
• The reactions involved can be expressed by:
  2Cu+Cl₂→2CuCl→2Cu↓+Cl₂↑
• The gases and the etching products that have not been involved in the reaction are exhausted through anexhaust port217.
• The source gas has been described, with the Cl₂gas diluted with, say, He or Ar taken as an example. However, the Cl₂gas can be used alone, or an HCl gas can also be applied. If the HCl gas is applied, an HCl gas plasma is generated as the source gas plasma. However, the precursor formed by etching of thecopper plate member207 is Cu_xCl_y. Thus, the source gas may be any gas containing chlorine, and a gas mixture of an HCl gas and a Cl₂gas is also usable. The material for thecopper plate member207 is not limited to copper (Cu), but it is possible to use a halide forming metal, preferably a chloride forming metal, such as Ag, Au, Pt, Ta, Ti or W. In this case, the resulting precursor is a halide (chloride) of Ag, Au, Pt, Ta, Ti or W, and the thin film formed on the surface of thesubstrate203 is that of Ag, Au, Pt, Ta, Ti or W.
• Since the metal film production apparatus constructed as above uses the Cl₂gas plasma (source gas plasma)214, the reaction efficiency is markedly increased, and the speed of film formation is fast. Since the Cl₂gas is used as the source gas, moreover, the cost can be markedly decreased. Furthermore, thesubstrate203 is controlled to a lower temperature than the temperature of thecopper plate member207 by use of the temperature control means206. Thus, the amounts of impurities, such as chlorine, remaining in thethin Cu film216 can be decreased, so that a high qualitythin Cu film216 can be produced.
• Furthermore, the plasma density of the Cl₂gas plasma214 is higher on the wall surface side. Thus, a high density Cl₂gas plasma214 can be generated, thus making the film formation speed remarkably high. Even when alarge chamber201 is used, namely, even for alarge substrate203, athin Cu film216 can be formed.
• Diluent gas nozzles221 are provided, as diluent gas supply means, for supplying an Ar gas, as a diluent gas, to the interior of thechamber201 above the surface of thesubstrate203. The Ar gas is supplied from thediluent gas nozzle221, and electromagnetic waves are shot from theplasma antenna209 into thechamber201, whereby the Ar gas is ionized to generate an Ar gas plasma (surface treatment plasma generation means). Abias power source220 is connected to thesupport platform202, and a bias voltage is applied thereto for supporting thesubstrate203 on thesupport platform202.
• In connection with the diluent gas supply means, when the Ar gas is applied as a diluent gas for the Cl₂gas, acontrol valve222 may be provided at the site of merger between the source gas (Cl₂gas) and the diluent gas (Ar gas), as shown inFIG. 30. By so doing, the Cl₂gas may be stopped during generation of the Ar gas plasma, and only the Ar gas may be supplied through thenozzle212. According to this construction, there is no need for the provision of thediluent gas nozzle221, presenting advantage in space.
• On the surface of thesubstrate203 carried into the above-described metal film production apparatus, thebarrier metal film223 of TaN has been formed, as shown inFIG. 31. By generating the Ar gas plasma, thebarrier metal film223 on the surface of thesubstrate203 is etched with Ar⁺ to flatten thebarrier metal film223. Also, denitrification is performed in which the nitrogen atoms (N) of the TaN in the superficial layer of thebarrier metal film223 are removed to decrease the nitrogen content of the superficial layer relative to the interior of the matrix of thebarrier metal film223. As thebarrier metal film223, WN or TiN can also be applied.
• The flattening of thebarrier metal film223 and its denitrification upon generation of the Ar gas plasma are carried out before formation of the aforementionedthin Cu film216. That is, when thesubstrate203 having thebarrier metal film223 of TaN formed thereon is received onto thesupport platform202, the Ar gas is supplied from thediluent gas nozzles221 prior to the formation of thethin Cu film216. At the same time, electromagnetic waves are shot from theplasma antenna209 into thechamber201 to generate an Ar gas plasma.
• Upon generation of the Ar gas plasma, the surface of thebarrier metal film223 is etched with Ar⁺ for flattening. As shown inFIG. 32, thebarrier metal film223 comprises Ta and N in an amorphous state. In this state, N of a lower mass is preferentially removed by Ar⁺, so that the superficial layer of the barrier metal film223 (for example, up to a half, preferably about a third, of the entire film thickness) is denitrified. As a result, there emerges thebarrier metal film223 of a two-layer structure, ametal layer223asubstantially composed of Ta, and aTaN layer223b, as shown inFIG. 33. On this occasion, the entire film thickness of thebarrier metal film223 remains the film thickness having the single layer.
• To increase the amount of Ar⁺ generated, control is exercised for increasing the voltage applied to theplasma antenna209, or for increasing the flow rate of the Ar gas. To draw in Ar⁺ toward thesubstrate203, thebias power source220 is controlled to lower the potential of thesubstrate203 to the negative side. For this purpose, schedule control is easy to effect according to a preset schedule. While denitrification is taking place, the depth distribution of themetal layer223ais measured. Control over the voltage of theplasma antenna209 or the flow rate of the Ar gas, or control of thebias power source220 can be exercised based on the results of the measurement.
• After denitrification is performed, the sites of N removed become voids, creating irregularities on the atomic level. Thus, it is preferred to densify the remaining Ta atoms. To make the Ta atoms dense, the present embodiment uses aheater204 to heat thesubstrate203 for heat treatment, thereby densifying the Ta atoms (densification means). The heat treatment is performed to such a degree that the atoms do not take a crystal structure (the atoms maintain an amorphous state). The densification means may be plasma heating for heating thesubstrate203.
• With the foregoing metal film production apparatus, the Ar gas plasma is generated within thechamber201 accommodating thesubstrate203 having thebarrier metal film223 formed thereon. The Ar gas plasma etches thebarrier metal film223 to flatten it. The Ar gas plasma also removes the nitrogen atoms to denitrify thebarrier metal film223. Thus, there appears thebarrier metal film223 with a two-layer structure, i.e., themetal layer223acomposed substantially of Ta and theTaN layer223b. Moreover, the entire film thickness can remain the single-layer film thickness. Hence, thebarrier metal film223 can be in a two-layer structure state without becoming thick, and yet themetal layer223acan retain adhesion to thethin Cu film216, while theTaN layer223bcan prevent diffusion of Cu. Consequently, thethin Cu film216 can be formed, with satisfactory adhesion, without diffusion into thesubstrate203, so that the Cu wiring process can be stabilized.
• A barrier metal film production method and a barrier metal film production apparatus according to the sixteenth embodiment of the present invention will be described with reference to FIGS.34 to36.FIG. 34 is a schematic side view of the metal film production apparatus according to the sixteenth embodiment of the present invention.FIG. 35 is a view taken along the arrowed line VIII-VIII ofFIG. 34.FIG. 36 is a view taken along the arrowed line IX-IX ofFIG. 35. The same members as the members illustrated inFIG. 29 are assigned the same numerals, and duplicate explanations are omitted.
• An upper surface of thechamber201 is an opening, which is closed with a disk-shapedceiling board230 made of an insulating material (for example, a ceramic). Anetched member231 made of a metal (copper, Cu) is interposed between the opening at the upper surface of thechamber201 and theceiling board230. The etchedmember231 is provided with aring portion232 fitted to the opening at the upper surface of thechamber201. A plurality of (12 in the illustrated embodiment)protrusions233, which extend close to the center in the diametrical direction of thechamber201 and have the same width, are provided in the circumferential direction on the inner periphery of thering portion232.
• Theprotrusions233 are integrally or removably attached to thering portion232. Notches (spaces)235 formed between theprotrusions233 are present between theceiling board230 and the interior of thechamber201. Thering portion232 is earthed, and theplural protrusions233 are electrically connected together and maintained at the same potential. Temperature control means (not shown), such as a heater, is provided in the etchedmember231 to control the temperature of the etchedmember231 to 200 to 400° C., for example.
• Second protrusions shorter in the diametrical direction than theprotrusions233 can be arranged between theprotrusions233. Moreover, short protrusions can be arranged between theprotrusion233 and the second protrusion. By so doing, the area of copper, an object to be etched, can be secured, with an induced current being suppressed.
• A planar winding-shapedplasma antenna234, for converting the atmosphere inside thechamber201 into a plasma, is provided above theceiling board230. Theplasma antenna234 is formed in a planar ring shape parallel to the surface of theceiling board230. A matchinginstrument210 and apower source211 are connected to theplasma antenna234 to supply power. The etchedmember231 has the plurality ofprotrusions233 provided in the circumferential direction on the inner periphery of thering portion232, and includes the notches (spaces)235 formed between theprotrusions233. Thus, theprotrusions233 are arranged between thesubstrate203 and theceiling board230 in a discontinuous state relative to the flowing direction of electricity in theplasma antenna234.
• With the above-described metal film production apparatus, the source gas is supplied through thenozzles212 to the interior of thechamber201, and electromagnetic waves are shot from theplasma antenna234 into thechamber201. As a result, the Cl₂gas is ionized to generate a Cl₂gas plasma (source gas plasma)214. The etchedmember231, an electric conductor, is present below theplasma antenna234. However, the Cl₂gas plasma214 occurs stably between theetched member231 and thesubstrate203, namely, below the etchedmember231, under the following action:
• The action by which the Cl₂gas plasma214 is generated below the etchedmember231 will be described. As shown inFIG. 36, a flow A of electricity in theplasma antenna234 of the planar ring shape crosses theprotrusions233. At this time, an induced current B occurs on the surface of theprotrusion233 opposed to theplasma antenna234. Since the notches (spaces)235 are present in the etchedmember231, the induced current B flows onto the lower surface of eachprotrusion233, forming a flow a in the same direction as the flow A of electricity in the plasma antenna234 (Faraday shield).
• When the etchedmember231 is viewed from thesubstrate203, therefore, there is no flow in a direction in which the flow A of electricity in theplasma antenna234 is canceled out. Furthermore, thering portion232 is earthed, and theprotrusions233 are maintained at the same potential. Thus, even though the etchedmember231, an electric conductor, exists, the electromagnetic wave is reliably thrown from theplasma antenna234 into thechamber201. Consequently, the Cl₂gas plasma214 is stably generated below the etchedmember231.
• The Cl₂gas plasma214 causes an etching reaction to the etchedmember231 made of copper, forming a precursor (Cu_xCl_y)215. At this time, the etchedmember231 is maintained by the Cl₂gas plasma214 at a predetermined temperature (e.g., 200 to 400° C.) which is higher than the temperature of thesubstrate203. The precursor (Cu_xCl_y)215 formed within thechamber201 is transported toward thesubstrate203 controlled to a lower temperature than the temperature of the etchedmember231. The precursor (Cu_xCl_y)215 transported toward thesubstrate203 is converted into only Cu ions by a reduction reaction, and directed at thesubstrate203 to form athin Cu film216 on the surface of thesubstrate203.
• The reactions involved are the same as in the aforementioned fifteenth embodiment. The gases and the etching products, which have not been involved in the reactions, are exhausted through anexhaust port217.
• Since the metal film production apparatus constructed as above uses the Cl₂gas plasma (source gas plasma)214, the reaction efficiency is markedly increased, and the speed of film formation is fast. Since the Cl₂gas is used as the source gas, moreover, the cost can be markedly decreased. Furthermore, thesubstrate203 is controlled to a lower temperature than the temperature of the etchedmember231 by use of the temperature control means206. Thus, the amounts of impurities, such as chlorine, remaining in thethin Cu film216 can be decreased, so that a high qualitythin Cu film216 can be produced.
• In addition, the etchedmember231 has the plurality ofprotrusions233 provided in the circumferential direction on the inner periphery of thering portion232, and includes the notches (spaces)235 formed between theprotrusions233. Thus, the induced currents generated in the etchedmember231 flow in the same direction as the flowing direction of electricity in theplasma antenna234, when viewed from thesubstrate203. Therefore, even though the etchedmember231, an electric conductor, exists below theplasma antenna234, the electromagnetic waves are reliably thrown from theplasma antenna234 into thechamber201. Consequently, the Cl₂gas plasma214 can be stably generated below the etchedmember231.
• Diluent gas nozzles221 are provided, as diluent gas supply means, for supplying an Ar gas, as a diluent gas, to the interior of thechamber201 above the surface of thesubstrate203. The Ar gas is supplied from thediluent gas nozzle221, and electromagnetic waves are shot from theplasma antenna234 into thechamber201, whereby the Ar gas is ionized to generate an Ar gas plasma (surface treatment plasma generation means). Abias power source220 is connected to thesupport platform202, and a bias voltage is applied thereto for supporting thesubstrate203 on thesupport platform202.
• On the surface of thesubstrate203 admitted into the above-described metal film production apparatus, thebarrier metal film223 of TaN has been formed, as shown inFIG. 31. By generating the Ar gas plasma, thebarrier metal film223 on the surface of thesubstrate203 is etched with Ar⁺ to flatten thebarrier metal film223. Also, denitrification is performed in which the nitrogen atoms (N) of the TaN in the superficial layer of thebarrier metal film223 are removed to decrease the nitrogen content of the superficial layer relative to the interior of the matrix of thebarrier metal film223. As thebarrier metal film223, WN or TiN can also be applied.
• The flattening of thebarrier metal film223 and its denitrification upon generation of the Ar gas plasma are carried out before formation of the aforementionedthin Cu film216. The details of the flattening of thebarrier metal film223, and the details of the denitrification of this film are the same as in the fifteenth embodiment, and relevant explanations are omitted.
• With the foregoing metal film production apparatus, as in the fifteenth embodiment, thebarrier metal film223 can be in a two-layer structure state without becoming thick, and yet themetal layer223acan retain adhesion to thethin Cu film216, while theTaN layer223bcan prevent diffusion of Cu. Consequently, thethin Cu film216 can be formed, with satisfactory adhesion, without diffusion into thesubstrate203, so that the Cu wiring process can be stabilized.
• A metal film production method and a metal film production apparatus according to the seventeenth embodiment of the present invention will be described with reference toFIG. 37.FIG. 37 is a schematic side view of the metal film production apparatus according to the seventeenth embodiment of the present invention. The same members as the members illustrated inFIGS. 2 and 7 are assigned the same numerals, and duplicate explanations are omitted.
• The opening of an upper portion of achamber201 is closed with aceiling board230, for example, made of a ceramic (an insulating material). Anetched member241 made of a metal (copper, Cu) is provided on a lower surface of theceiling board230, and the etchedmember241 is of a quadrangular pyramidal shape. Slit-shapedopening portions242 are formed at a plurality of locations (for example, four locations) in the periphery of an upper part of the cylindrical portion of thechamber201, and one end of atubular passage243 is fixed to each of the openingportions242. Atubular excitation chamber244 made of an insulator is provided halfway through thepassage243, and acoiled plasma antenna245 is provided around theexcitation chamber244. Theplasma antenna245 is connected to amatching instrument248 and apower source249 to receive power. Theplasma antenna245, the matchinginstrument248 and thepower source249 constitute plasma generation means.
• Aflow controller246 is connected to the other end of thepassage243, and a chlorine-containing source gas (a Cl₂gas diluted with He or Ar to a chlorine concentration of ≦50%, preferably about 10%) is supplied into thepassage243 via theflow controller246. By shooting electromagnetic waves from theplasma antenna245 into theexcitation chamber244, the Cl₂gas is ionized to generate a Cl₂gas plasma (source gas plasma)247. Because of the generation of the Cl₂gas plasma247, excited chlorine is fed into thechamber201 through the openingportion42, whereupon the etchedmember241 is etched with excited chlorine.
• With the above-described metal film production apparatus, the source gas is supplied into thepassage243 via theflow controller246 and fed into theexcitation chamber244. By shooting electromagnetic waves from theplasma antenna245 into theexcitation chamber244, the Cl₂gas is ionized to generate a Cl₂gas plasma (source gas plasma)247. Since a predetermined differential pressure has been established between the pressure inside thechamber201 and the pressure inside theexcitation chamber244 by thevacuum device208, the excited chlorine of the Cl₂gas plasma247 in theexcitation chamber244 is fed to the etchedmember241 inside thechamber201 through theopening portion242. The excited chlorine causes an etching reaction to the etchedmember241, forming a precursor (M_xCl_y)215 inside thechamber201.
• At this time, the etchedmember241 is maintained at a predetermined temperature (e.g., 200 to 400° C.), which is higher than the temperature of thesubstrate203, by aheater250. The precursor (Cu_xCl_y)215 formed inside thechamber201 is transported toward thesubstrate203 controlled to a lower temperature than the temperature of the etchedmember241. The precursor (Cu_xCl_y)215 transported toward thesubstrate203 is converted into only Cu ions by a reduction reaction, and directed at thesubstrate203 to form athin Cu film216 on the surface of thesubstrate203.
• The reactions on this occasion are the same as in the aforementioned fifteenth embodiment, and the gases and etching products that have not been involved in the reactions are exhausted through anexhaust port217.
• With the above-described metal film production apparatus, the Cl₂gas plasma247 is generated in theexcitation chamber244 isolated from thechamber201. Thus, thesubstrate203 is not exposed to the plasma any more, and thesubstrate203 becomes free from damage from the plasma. As the means for generating the Cl₂gas plasma247 in theexcitation chamber244, it is possible to use microwaves, laser, electron rays, or synchrotron radiation. It is also permissible to form the precursor by heating a metal filament to a high temperature. The construction for isolating the Cl₂gas plasma247 from thesubstrate203 may be the provision of theexcitation chamber244 in thepassage243, or may be other construction, for example, the isolation of thechamber201.
• The above-described metal film production apparatus is provided withdiluent gas nozzles221, as diluent gas supply means, for supplying an Ar gas, as a diluent gas, to the interior of thechamber201 above the surface of thesubstrate203. A coil-shaped surfacetreatment plasma antenna236 is provided on a trunk portion of thechamber201. A matchinginstrument237 and apower source238 are connected to the surfacetreatment plasma antenna236 to supply power. The Ar gas is supplied from thediluent gas nozzles221, and electromagnetic waves are shot from theplasma antenna236 into thechamber201, whereby the Ar gas is ionized to generate an Ar gas plasma (surface treatment plasma generation means). Abias power source220 is connected to thesupport platform202, and a bias voltage is applied thereto for supporting thesubstrate203 on thesupport platform202.
• On the surface of thesubstrate203 admitted into the above-described metal film production apparatus, abarrier metal film223 of TaN has been formed, as shown inFIG. 31. By generating the Ar gas plasma, thebarrier metal film223 on the surface of thesubstrate203 is etched with Ar⁺ to flatten thebarrier metal film223. Also, denitrification is performed in which the nitrogen atoms (N) of the TaN in the superficial layer of thebarrier metal film223 are removed to decrease the nitrogen content of the superficial layer relative to the interior of the matrix of thebarrier metal film223. As thebarrier metal film223, WN or TiN can also be applied.
• The flattening of thebarrier metal film223 and its denitrification upon generation of the Ar gas plasma are carried out before formation of the aforementionedthin Cu film216. The details of the flattening of thebarrier metal film223 and the denitrification of this film are the same as in the fifteenth embodiment, and relevant explanations are omitted.
• With the foregoing metal film production apparatus, thebarrier metal film223 can be in a two-layer structure state without becoming thick, and yet themetal layer223a(seeFIG. 33) can retain adhesion to thethin Cu film216, while theTaN layer223b(seeFIG. 33) can prevent diffusion of Cu. Consequently, thethin Cu film216 can be formed, with satisfactory adhesion, without diffusion into thesubstrate203, so that the Cu wiring process can be stabilized.
• A barrier metal film production method and a barrier metal film production apparatus according to the eighteenth embodiment of the present invention will be described with reference toFIG. 38.FIG. 38 is a schematic side view of the metal film production apparatus according to the eighteenth embodiment of the present invention. The same members as the members illustrated inFIGS. 29, 34 and37 are assigned the same numerals, and duplicate explanations are omitted.
• Compared with the metal film production apparatus of the fifteenth embodiment shown inFIG. 29, theplasma antenna209 is not provided around the cylindrical portion of thechamber201, and thematching instrument210 andpower source211 are connected to thecopper plate member207 for supply of power to thecopper plate member207. With the above-described metal film production apparatus, the source gas is supplied from thenozzles212 into thechamber201, and electromagnetic waves are shot from thecopper plate member207 into thechamber201, the Cl₂gas is ionized to generate a Cl₂gas plasma (source gas plasma)214. The Cl₂gas plasma214 causes an etching reaction to thecopper plate member207, forming a precursor (Cu_xCl_y)215. At this time, thecopper plate member207 is maintained at a predetermined temperature (e.g., 200 to 400° C.), which is higher than the temperature of thesubstrate203, by the Cl₂gas plasma214.
• The precursor (Cu_xCl_y)215 formed inside thechamber201 is transported toward thesubstrate203 controlled to a lower temperature than the temperature of thecopper plate member207. The precursor (Cu_xCl_y)215 transported toward thesubstrate203 is converted into only Cu ions by a reduction reaction, and directed at thesubstrate203 to form athin Cu film216 on the surface of thesubstrate203. The reactions on this occasion are the same as in the aforementioned fifteenth embodiment, and the gases and etching products that have not been involved in the reactions are exhausted through anexhaust port217.
• With the above-described metal film production apparatus, thecopper plate member207 itself is applied as an electrode for plasma generation. Thus, theplasma antenna209 intended to prepare thethin Cu film216 need not be provided around the cylindrical portion of thechamber201.
• The above-described metal film production apparatus is provided withdiluent gas nozzles221, as diluent gas supply means, for supplying an Ar gas, as a diluent gas, to the interior of thechamber201 above the surface of thesubstrate203. Supply of the source gas through thenozzles212 is cut off, the Ar gas is supplied from thediluent gas nozzles221, and electromagnetic waves are shot from thecopper plate member207 into thechamber201. By so doing, the Ar gas is ionized to generate an Ar gas plasma (surface treatment plasma generation means). Abias power source220 is connected to thesupport platform202, and a bias voltage is applied thereto for supporting thesubstrate203 on thesupport platform202.
• On the surface of thesubstrate203 admitted into the above-described metal film production apparatus, abarrier metal film223 of TaN has been formed, as shown inFIG. 31. By generating the Ar gas plasma, thebarrier metal film223 on the surface of thesubstrate203 is etched with Ar⁺ to flatten thebarrier metal film223. Also, denitrification is performed in which the nitrogen atoms (N) of the TaN in the superficial layer of thebarrier metal film223 are removed to decrease the nitrogen content of the superficial layer relative to the interior of the matrix of thebarrier metal film223. As thebarrier metal film223, WN or TiN can also be applied. As the surface treatment plasma generation means, it is permissible to provide a coiled surface treatment plasma antenna on the trunk portion of thechamber201, and supply power via a matching instrument and a power source, thereby generating an Ar gas plasma.
• The flattening of thebarrier metal film223 and its denitrification upon generation of the Ar gas plasma are carried out before formation of the aforementionedthin Cu film216. The details of the flattening of thebarrier metal film223 and the denitrification of this film are the same as in the fifteenth embodiment, and relevant explanations are omitted.
• With the foregoing metal film production apparatus, as in the fifteenth embodiment, thebarrier metal film223 can be in a two-layer structure state without becoming thick, and themetal layer223a(seeFIG. 33) can retain adhesion to thethin Cu film216, while theTaN layer223b(seeFIG. 33) can prevent diffusion of Cu. Consequently, thethin Cu film216 can be formed, with satisfactory adhesion, without diffusion into thesubstrate203, so that the Cu wiring process can be stabilized.
• Next, an example in which embodiments of the metal film production method and metal film production apparatus according to the first aspect are provided in thebarrier metal CVD403 will be described with reference toFIG. 39.FIG. 39 schematically shows a side view of the metal film production apparatus according to the nineteenth embodiment of the present invention.
• As shown in the drawing, asupport platform252 is provided near the bottom of a cylindrical chamber251 made of, say, a ceramic (an insulating material), and asubstrate253 is placed on thesupport platform252. Temperature control means256 equipped with aheater254 and refrigerant flow-throughmeans255 is provided in thesupport platform252 so that thesupport platform252 is controlled to a predetermined temperature (for example, a temperature at which thesubstrate253 is maintained at 100 to 200° C.) by the temperature control means256.
• An upper surface of the chamber251 is an opening, which is closed with ametal member257, as an etched member, made of a metal (e.g., W, Ti, Ta, or TiSi). The interior of the chamber251 closed with themetal member257 is maintained at a predetermined pressure by avacuum device258. Aplasma antenna259, as a coiled winding antenna of plasma generation means, is provided around a cylindrical portion of the chamber251. A matching instrument260 and apower source261 are connected to theplasma antenna259 to supply power.
• Nozzles262 for supplying a source gas (a Cl₂gas diluted with He or Ar to a chlorine concentration of ≦50%, preferably about 10%), containing chlorine as a halogen, to the interior of the chamber251 are connected to the cylindrical portion of the chamber251 below themetal member257. Thenozzle262 is open toward the horizontal, and is fed with the source gas via a flow controller263 (halogen gas supply means). Fluorine (F), bromine (Br) or iodine (I) can also be applied as the halogen to be incorporated into the source gas.
• Slit-shapedopening portions264 are formed at a plurality of locations (for example, four locations) in the periphery of a lower part of the cylindrical portion of the chamber251, and one end of atubular passage265 is fixed to each of the openingportions264. Atubular excitation chamber266 made of an insulator is provided halfway through thepassage265, and acoiled plasma antenna267 is provided around theexcitation chamber266. Theplasma antenna267 is connected to amatching instrument268 and apower source269 to receive power. Theplasma antenna267, the matchinginstrument268 and thepower source269 constitute excitation means. Aflow controller270 is connected to the other end of thepassage265, and an ammonia gas (NH₃gas) as a nitrogen-containing gas is supplied into thepassage265 via theflow controller270.
• With the above-described metal film production apparatus, the source gas is supplied through thenozzles262 to the interior of the chamber251, and electromagnetic waves are shot from theplasma antenna259 into the chamber251. As a result, the Cl₂gas is ionized to generate a Cl₂gas plasma (source gas plasma)271. The Cl₂gas plasma271 causes an etching reaction to themetal member257, forming a precursor (M_xCl_y: M is a metal such as W, Ti, Ta or TiSi)272.
• Separately, the NH₃gas is supplied into thepassage265 via theflow controller270 and fed into theexcitation chamber266. By shooting electromagnetic waves from theplasma antenna267 into theexcitation chamber266, the NH₃gas is ionized to generate an NH₃gas plasma263. Since a predetermined differential pressure has been established between the pressure inside the chamber251 and the pressure inside theexcitation chamber266 by thevacuum device258, the excited ammonia of the NH₃gas plasma273 in theexcitation chamber266 is fed to the precursor (M_xCl_y)272 inside the chamber251 through theopening portion264.
• That is, excitation means for exciting the nitrogen-containing gas in theexcitation chamber266 isolated from the chamber251 is constructed. Because of this construction, the metal component of the precursor (M_xCl_y)272 and ammonia react to form a metal nitride (MN) (formation means). At this time, themetal member257 and theexcitation chamber266 are maintained by the plasmas at predetermined temperatures (e.g., 200 to 400° C.) which are higher than the temperature of thesubstrate253.
• The metal nitride (MN) formed within the chamber251 is transported toward thesubstrate253 controlled to a low temperature, whereby a thin MN film274 (a TaN film if themetal member257 of Ta is applied) is formed on the surface of thesubstrate253.
• The reaction for formation of the thin MN film274 can be expressed by:
  2MCl+2NH₃→2MN↓+HCl↑+2H₂↑
• The gases and the etching products that have not been involved in the reactions are exhausted through anexhaust port277.
• The source gas has been described, with the Cl₂gas diluted with, say, He or Ar taken as an example. However, the Cl₂gas can be used alone, or an HCl gas can also be applied. When the HCl gas is applied, an HCl gas plasma is generated as the source gas plasma. Thus, the source gas may be any gas containing chlorine, and a gas mixture of an HCl gas and a Cl₂gas is also usable. As the material for themetal member257, it is possible to use an industrially applicable metal such as Ag, Au, Pt or Si. Further, the NH₃gas is supplied into thepassage265 and fed into theexcitation chamber266. At the same time, electromagnetic waves are shot from theplasma antenna267 into theexcitation chamber266 to generate the NH₃gas plasma263. However, an NH₃gas plasma can be generated within the chamber251 by supplying an NH₃gas into the chamber251 and supplying power to theplasma antenna259. In this case, thechamber265,excitation chamber266,plasma antenna267, matchinginstrument268 andpower source269 can be omitted.
• With the above-described metal film production apparatus, the metal is formed by plasmas to produce the thin MN film274 as the barrier metal film. Thus, the barrier metal film can be formed uniformly to a small thickness. Consequently, the barrier metal film can be formed highly accurately at a high speed with excellent burial properties in a very small thickness even to the interior of a tiny depression, for example, several hundred nanometers wide, which has been provided in thesubstrate253.
• The above-described metal film production apparatus is provided withdiluent gas nozzles276, as diluent gas supply means, for supplying an Ar gas, as a diluent gas, to the interior of the chamber251 above the surface of thesubstrate253. The Ar gas is supplied from thediluent gas nozzles276, and electromagnetic waves are shot from theplasma antenna259 into the chamber251, whereby the Ar gas is ionized to generate an Ar gas plasma (surface treatment plasma generation means). Abias power source277 is connected to thesupport platform252, and a bias voltage is applied thereto for supporting thesubstrate253 on thesupport platform252.
• With the above-described metal film production apparatus, the thin MN film274 as a barrier metal film is formed, whereafter an Ar gas plasma is generated. By generating the Ar gas plasma, the barrier metal film on the surface of thesubstrate253 is etched with Ar⁺ to flatten the barrier metal film. Also, denitrification is performed in which the nitrogen atoms (N) of the TaN in the superficial layer of the barrier metal film are removed. After flattening of the barrier metal film and the removal of the nitrogen atoms (N) of the TaN in the superficial layer for denitrification, a thin copper (Cu) film or a thin aluminum (Al) film is formed on the barrier metal film by a film forming device. The details of the flattening of the barrier metal film and the denitrification of this film upon generation of the Ar gas plasma are the same as in the fifteenth embodiment. Thus, relevant explanations are omitted.
• With the foregoing metal film production apparatus, as in the fifteenth embodiment, the barrier metal film can be in a two-layer structure state without becoming thick, and the resulting metal layer can retain adhesion to a thin metal film formed by film formation in the subsequent step. Whereas the TaN layer can prevent diffusion of metal during film formation in the subsequent step. Consequently, the thin metal film (thin Cu film) during film formation in the subsequent step can be formed, with satisfactory adhesion, without diffusion into thesubstrate253, so that the Cu wiring process can be stabilized.
• The construction of the metal film production apparatus for producing the barrier metal film may employ a device of the type generating a capacitive coupling plasma, or a device of the remote type which generates a plasma in a manner isolated from a film formation chamber.
• Next, the second aspect of the present invention will be described. According to the second aspect, the barrier metal film of TaN is subjected to a surface treatment in which this film is reacted in a reducing gas (e.g. hydrogen gas) atmosphere (a hydrogen gas plasma) to remove the nitrogen atoms in the superficial layer of the barrier metal film, thereby decreasing the nitrogen content of the superficial layer relative to the interior of the matrix of the barrier metal film (this treatment will be referred to hereinafter as denitrification). The denitrification brings a state in which a film of the metal (Ta) is substantially formed in the superficial layer of the single-layer barrier metal film. In this manner, a barrier metal film is produced highly efficiently and reliably in a thin film condition, with the diffusion of the metal being prevented and the adhesion to the metal being maintained.
• As the reducing gas, a nitrogen gas as well as the hydrogen gas can be applied, or a carbon monoxide gas can also be applied. If the carbon monoxide gas is used, denitrification can be carried out in a carbon monoxide gas atmosphere, without generation of plasma.
• The concrete construction of the apparatus according to the second aspect of the invention may be as follows: A source gas containing a halogen (e.g., a chlorine-containing gas) is supplied to the interior of a chamber between a substrate and an etched member of Ta, and an atmosphere within the chamber is converted into a plasma to generate a chlorine gas plasma. The etched member is etched with the chlorine gas plasma to form a precursor comprising the Ta component contained in the etched member and the chlorine gas. Also, a nitrogen-containing gas is excited, and TaN, a metal nitride, is formed upon reaction between the excited nitrogen and the precursor. The resulting TaN is formed as a film on the substrate kept at a low temperature to form a barrier metal film. This process is performed using a barrier metal film production apparatus. After the barrier metal film is produced in this manner, a hydrogen gas plasma (or a nitrogen gas plasma) is generated within the chamber to react radical hydrogen with nitrogen, performing denitrification. That is, the barrier metal film production apparatus shown inFIG. 39 can be applied.
• Alternatively, the concrete construction of the apparatus of the second aspect may be as follows: A chlorine gas is supplied into the chamber, and an atmosphere within the chamber is converted into a plasma to generate a chlorine gas plasma. An etched member made of copper (Cu) is etched with the chlorine gas plasma to form a precursor comprising the Cu component contained in the etched member and chlorine inside the chamber. The temperature of the substrate is rendered lower than the temperature of the etched member to form a film of the Cu component of the precursor on the substrate. This process is performed using a metal film forming device. Before the substrate having a barrier metal film of TaN formed thereon is housed in the chamber and the Cu component is formed as a film thereon, a hydrogen gas plasma (or a nitrogen gas plasma) is generated within the chamber to react radical hydrogen with nitrogen, performing denitrification. That is, the metal film production apparatus shown, for example, in FIGS.29,34,37 and38 can be applied.
• Embodiments of the metal film production method and metal film production apparatus according to the second aspect will be described, with the provision of the apparatus in the Cu-CVD404 (seeFIG. 28) being taken as an example.
• FIG. 40 shows the conceptual construction of a metal film production apparatus according to the twentieth embodiment of the present invention.FIG. 41 shows the concept status of the barrier metal film in denitrification. The illustrated metal film production apparatus has the conceptual construction of the metal film production apparatus according to the fifteenth embodiment shown inFIG. 29, in which the gas supplied through thenozzle21 is different. Thus, the formation of the thin Cu film in the metal film production apparatus is the same, and its explanation is omitted hereinbelow.
• As shown inFIG. 40, reducinggas nozzles225 are provided, as reducing gas supply means, for supplying a hydrogen gas (H₂gas) as a reducing gas, to the interior of achamber201 above the surface of asubstrate203. The H₂gas is supplied from the reducinggas nozzles225, and electromagnetic waves are shot from aplasma antenna209 into thechamber201, whereby the H₂gas is ionized to generate an H₂gas plasma (surface treatment means). On the surface of thesubstrate203 admitted into the illustrated metal film production apparatus, abarrier metal film223 of TaN (seeFIG. 31) has been formed. Upon generation of the H₂gas plasma, hydrogen radicals H* react with the nitrogen atoms (N) of the TaN in the superficial layer of thesubstrate203, forming ammonia NH₃, which is exhausted. Thus, the nitrogen atoms (N) in the superficial layer are removed to decrease the nitrogen content of the superficial layer relative to the interior of the matrix of the barrier metal film223 (denitrification).
• The denitrification of the barrier metal film223 (seeFIG. 31) caused by generation of the H₂gas plasma is performed before formation of thethin Cu film216 explained in the fifteenth embodiment ofFIG. 29. That is, when thesubstrate203 having thebarrier metal film223 of TaN (seeFIG. 31) formed thereon is admitted onto asupport platform202, the H₂gas is supplied from the reducinggas nozzles225 prior to the formation of the thin Cu film216 (seeFIG. 29). At the same time, electromagnetic waves are shot from theplasma antenna209 into thechamber201, whereby the H₂gas plasma is generated.
• Upon generation of the H₂gas plasma, hydrogen radicals H* react with the nitrogen atoms (N) of the TaN in the superficial layer of thesubstrate203, forming ammonia NH₃, which is exhausted. The hydrogen radicals H* do not affect the metal, but react with only the nitrogen atoms (N), thereby forming ammonia NH₃.
• That is, the reaction
  N+3H*→NH₃
  forms ammonia NH₃, which is exhausted.
• As shown inFIG. 41, thebarrier metal film223 comprises Ta and N in an amorphous state. In this state, hydrogen radicals H* react with N, forming ammonia NH₃, which is exhausted. In this manner, the superficial layer of the barrier metal film223 (for example, up to a half, preferably about a third, of the entire film thickness) is denitrified. As a result, there emerges thebarrier metal film223 of a two-layer structure, ametal layer223asubstantially composed of Ta, and aTaN layer223b, as shown inFIG. 33. On this occasion, the entire film thickness of thebarrier metal film223 remains the film thickness constructed by the single layer.
• Hydrogen radicals H* have a short life and penetrate narrow sites. Thus, the pressure inside thechamber201 is lowered to decrease the density, or the temperature of thesubstrate203 is controlled, thereby making it possible to increase hydrogen radicals H* (prevent them from colliding with each other), or to control the depth of themetal layer223acomposed substantially of Ta (seeFIG. 33). Setting of the pressure can be performed by increasing the mean free path (MFP) which is the value of the distance traveled by a hydrogen radical H* before collision. Normally, the distance from the center of the plasma to thesubstrate203 depends on the apparatus. To increase the mean free path, control is exercised, with the pressure inside thechamber201 being lowered. If the apparatus has thesupport platform202 movable upward and downward, thesupport platform202 is raised, without a fall in the pressure, to bring thesubstrate203 close to the center of the plasma, whereby the mean free path can be increased relatively.
• With the foregoing metal film production apparatus, the hydrogen gas plasma is generated within thechamber201 accommodating thesubstrate203 having thebarrier metal film223 formed thereon. The hydrogen radicals H* take part in denitrification in which they react with the nitrogen atoms (N), forming ammonia NH₃, which is exhausted. Thus, there can appear thebarrier metal film223 with a two-layer structure, i.e., themetal layer223acomposed substantially of Ta (seeFIG. 33) and theTaN layer223b(seeFIG. 33). Moreover, the entire film thickness can remain the single-layer film thickness. Hence, thebarrier metal film223 can be in a two-layer structure state without becoming thick, and yet themetal layer223a(seeFIG. 33) can retain adhesion to the thin Cu film216 (seeFIG. 29), while theTaN layer223b(seeFIG. 33) can prevent diffusion of Cu. Consequently, the thin Cu film216 (seeFIG. 29) can be formed, with satisfactory adhesion, without diffusion into thesubstrate203, so that the Cu wiring process can be stabilized. In addition, denitrification can be carried out with high efficiency.
• The hydrogen gas has been taken as an example of the reducing gas for the purpose of explanation. In the case of the metal film production apparatus in which a hydrogen atmosphere is not usable, a nitrogen gas can be used as the reducing gas. In this case, a nitrogen gas plasma is generated, whereupon N* reacts with the nitrogen atoms (N) of thebarrier metal film223. As a result, N+N*→N₂, which is exhausted. The use of the nitrogen gas enables denitrification to take place easily, even if a limitation is imposed on the use of the reducing gas.
• Alternatively, a carbon monoxide gas can be used as the reducing gas. In this case, no plasma is generated, and in the unchanged atmosphere, CO reacts with the nitrogen atoms (N) of thebarrier metal film223, as in 2N+2CO→2CN+O₂, which are exhausted. The use of the carbon monoxide gas enables denitrification to take place, simply by temperature control of thesubstrate203 without generation of a plasma. Thus, consumption of power can be decreased.
• The twentieth embodiment described above can be applied to the metal film production apparatuses of the sixteenth to eighteenth embodiments shown inFIGS. 34, 37 and38. It is also applicable to the barrier metal film production apparatus of the nineteenth embodiment shown inFIG. 39. It is also possible to combine the flattening of the surface with Ar⁺ upon generation of the Ar gas plasma in the fifteenth to nineteenth embodiments with denitrification using the reducing gas plasma. In this case, an Ar gas and a reducing gas may be mixed and supplied into thechamber1, or an Ar gas and a reducing gas may be supplied sequentially.
• Next, the third aspect of the present invention will be described. According to the third aspect, a barrier metal film of TaN is subjected to a treatment for etching the surface and forming nuclei of silicon atoms by use of a plasma of a silicon-containing gas (for example, silane, SiH₄, a hydride of silicon). Silicon, which is not a foreign matter, has good adhesion to a metal, and the formation of nuclei of silicon atoms on the surface can increase adhesion between the metal of a barrier metal film and a metal to be formed as a film thereon. By this method, a barrier metal film preventing diffusion of a metal and retaining adhesion to the metal is produced with good efficiency and without deterioration of performance.
• As the silicon-containing gas, a disilane (Si₂H₆) gas or a trisilane (Si₃H₈) can be used in addition to the SiH₄gas. If hydrogen cannot be used, an SiCl₄gas, an SiH₂Cl₂gas or an SiHCl₃gas can be applied. Any such gas may be diluted with a diluent gas and supplied. By controlling the dilution ratio or the flow rate of the gas, or controlling the power of its plasma, it becomes possible to control the depth of etching on the surface or the sizes of the nuclei of silicon atoms.
• A concrete apparatus construction according to the third aspect of the invention may be as follows: Using a barrier metal film production apparatus, a source gas containing a halogen (e.g., a chlorine-containing gas) is supplied to the interior of a chamber between a substrate and an etched member of Ta, and an atmosphere within the chamber is converted into a plasma to generate a chlorine gas plasma. The etched member is etched with the chlorine gas plasma to form a precursor comprising the Ta component contained in the etched member and the chlorine gas. Also, a nitrogen-containing gas is excited, and TaN, a metal nitride, is formed upon reaction between the excited nitrogen and the precursor. The resulting TaN is formed as a film on the substrate kept at a low temperature to form a barrier metal film. After the barrier metal film is produced in this manner, an SiH₄gas plasma, a gas containing silicon, is generated within the chamber to form crystal grains of Si. That is, a barrier metal film production apparatus shown, for example, inFIG. 39 can be applied.
• Alternatively, a concrete apparatus construction according to the third aspect of the invention may be as follows: A chlorine gas is supplied into the chamber, and an atmosphere within the chamber is converted into a plasma to generate a chlorine gas plasma. An etched member made of copper (Cu) is etched with the chlorine gas plasma to form a precursor comprising the Cu component contained in the etched member and chlorine inside the chamber. The temperature of the substrate is rendered lower than the temperature of the etched member to form a film of the Cu component of the precursor on the substrate. This process is performed using a metal film forming device. The substrate having a barrier metal film of TaN formed thereon is housed in the chamber. Before the Cu component is formed as a film thereon, an SiH₄gas plasma, a plasma of a silicon-containing gas, is generated within the chamber to form crystal grains of Si. That is, the metal film production apparatus shown, for example, inFIG. 29, 34,37 or38 can be applied.
• An embodiment of the metal film production method and metal film production apparatus according to the third aspect will be described, with the provision of the apparatus in the Cu-CVD404 (seeFIG. 28) being taken as an example.
• FIG. 42 shows the conceptual construction of a metal film production apparatus according to the twenty-first embodiment of the present invention.FIG. 43 shows the concept status of a barrier metal film in the formation of nuclei of Si. The illustrated metal film production apparatus has the conceptual construction of the metal film production apparatus according to the fifteenth embodiment shown inFIG. 29, in which the gas supplied through thenozzles21 is made different. Thus, the formation of the thin Cu film in the metal film production apparatus is the same, and its explanation is omitted hereinbelow.
• As shown inFIG. 42, silicon-containinggas nozzles228 are provided, as silicon-containing gas supply means, for supplying a silane gas (SiH₄gas), as a gas containing silicon, to the interior of achamber201 above the surface of asubstrate203. An SiH₄gas diluted with hydrogen is supplied through the silicon-containinggas nozzles228, and electromagnetic waves are shot from aplasma antenna209 into thechamber201, whereby the hydrogen-diluted SiH₄gas is ionized to generate an SiH₄gas plasma (surface treatment plasma means). On the surface of thesubstrate203 admitted into the illustrated metal film production apparatus, abarrier metal film223 of TaN (seeFIG. 31) has been formed. Generation of the SiH₄gas plasma results in the growth of crystal grains of Si and the appearance of H₂. While film formation is proceeding, crystal grains of Si are formed as nuclei on the superficial layer of thesubstrate203 by the etching action of H₂.
• The formation of the nuclei of Si upon generation of the SiH₄gas plasma is performed before formation of thethin Cu film216 explained in the fifteenth embodiment ofFIG. 29. That is, when thesubstrate203 having thebarrier metal film223 of TaN (seeFIG. 31) formed there on is admitted onto thesupport platform202, a hydrogen-diluted SiH₄gas is supplied through the silicon-containinggas nozzles228 prior to the formation of the thin Cu film216 (seeFIG. 29). Also, electromagnetic waves are shot from theplasma antenna209 into thechamber201 to generate an SiH₄gas plasma. The ratio of SiH₄to hydrogen in the hydrogen-diluted SiH₄gas is set, for example, as follows: SiH₄/hydrogen≦5/100. As the diluent gas, argon, helium, neon or other diluent gas can be applied in addition to hydrogen.
• When the SiH₄gas plasma is generated, the reaction
  SiH₄→Si+H₂
  proceeds. As a result, while film formation is proceeding, crystal grains of Si are formed as nuclei on the superficial layer of thebarrier metal film223 by the etching action of H₂, as shown inFIG. 43. The sizes of the nuclei of Si can be controlled appropriately by controlling the conditions for the plasma, the ratio of hydrogen dilution, the flow rate of the gas, etc. The etching action of H₂removes the nitrogen atoms (N) of thebarrier metal film223, and can bring the state of thebarrier metal film223 having a two-layer structure, ametal layer223asubstantially composed of Ta (seeFIG. 33), and aTaN layer223b(seeFIG. 33).
• Since the SiH₄gas is diluted with hydrogen, the crystallinity of Si can be improved, and its nuclei are easy to form. Silicon, which is not a foreign matter, has good adhesion to Ta and Cu, and the formation of nuclei of Si on the surface of thebarrier metal film223 can increase adhesion between Ta of thebarrier metal film223 and Cu to be formed as a film thereon. By this method, abarrier metal film223 preventing diffusion of the metal and retaining adhesion to the metal is produced with good efficiency and without deterioration of performance.
• With the above-described metal film production apparatus, the SiH₄gas plasma is generated within thechamber201 accommodating thesubstrate203 having thebarrier metal film223 formed thereon, whereby crystal grains of Si are formed as nuclei on the superficial layer of thebarrier metal film223. Thus, adhesion to Ta and Cu can be improved. Consequently, thebarrier metal film223 can be formed with satisfactory adhesion and anti-diffusion properties without becoming thick, so that the Cu wiring process can be stabilized.
• The twenty-first embodiment described above can be applied to the metal film production apparatuses of the sixteenth to eighteenth embodiments shown inFIGS. 34, 37 and38. It is also applicable to the barrier metal film production apparatus of the nineteenth embodiment shown inFIG. 39. It is also possible to combine the flattening of the surface with Ar⁺ upon generation of the Ar gas plasma in the fifteenth to nineteenth embodiments with the formation of crystal grains of Si as nuclei on the superficial layer of thebarrier metal film223. In this case, a common nozzle can be used by diluting an SiH₄gas with an Ar gas, and the flattening of the surface and the formation of Si nuclei can be easily switched by controlling the flow rate of the Ar gas.
• While the present invention has been described by the foregoing embodiments, it is to be understood that the invention is not limited thereby, but may be varied in many other ways. Such variations are not to be regarded as a departure from the spirit and scope of the invention, and all such modifications as would be obvious to one skilled in the art are intended to be included within the scope of the appended claims.

Claims (10)

1. A barrier metal film production apparatus, comprising:

a chamber accommodating a substrate;

a metallic etched member provided in the chamber at a position opposed to the substrate;

source gas supply means for supplying a source gas containing a halogen to an interior of the chamber between the substrate and the etched member;

plasma generation means which converts an atmosphere within the chamber into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas;

excitation means for exciting a nitrogen-containing gas in a manner isolated from the chamber;

formation means for forming a metal nitride upon reaction between nitrogen excited by the excitation means and the precursor; and

control means which makes a temperature of the substrate lower than a temperature of the formation means to form the metal nitride as a film on the substrate.

2. A barrier metal film production apparatus, comprising:

a chamber accommodating a substrate;

a metallic etched member provided in the chamber at a position opposed to the substrate;

source gas supply means for supplying a source gas containing a halogen to an interior of the chamber between the substrate and the etched member;

plasma generation means which converts an atmosphere within the chamber into a plasma to generate a source gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas;

excitation means for exciting a nitrogen-containing gas in a manner isolated from the chamber;

formation means for forming a metal nitride upon reaction between nitrogen excited by the excitation means and the precursor; and

control means which makes a temperature of the substrate lower than a temperature of the formation means to form the metal nitride as a film on the substrate, and after film formation of the metal nitride, stops supply of the nitrogen-containing gas, and makes the temperature of the substrate lower than a temperature of the etched member to form the metal component of the precursor as a film on the metal nitride on the substrate.

3. A barrier metal film production apparatus, comprising:

a chamber accommodating a substrate;

a metallic etched member provided in the chamber at a position opposed to the substrate;

source gas supply means for supplying a source gas containing a halogen to an interior of the chamber between the substrate and the etched member;

nitrogen-containing gas supply means for supplying a nitrogen-containing gas to an interior of the chamber between the substrate and the etched member;

plasma generation means which converts an atmosphere within the chamber into a plasma to generate a source gas plasma and a nitrogen-containing gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas, and that a metal nitride is formed upon reaction between nitrogen and the precursor; and

control means which makes a temperature of the substrate lower than a temperature of the etched member to form the metal nitride as a film on the substrate.

4. A barrier metal film production apparatus, comprising:

a chamber accommodating a substrate;

a metallic etched member provided in the chamber at a position opposed to the substrate;

source gas supply means for supplying a source gas containing a halogen to an interior of the chamber between the substrate and the etched member;

nitrogen-containing gas supply means for supplying a nitrogen-containing gas to an interior of the chamber between the substrate and the etched member;

plasma generation means which converts an atmosphere within the chamber into a plasma to generate a source gas plasma and a nitrogen-containing gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas, and that a metal nitride is formed upon reaction between nitrogen and the precursor; and

control means which makes a temperature of the substrate lower than a temperature of the etched member to form the metal nitride as a film on the substrate, and then stops supply of the nitrogen-containing gas, and makes the temperature of the substrate lower than the temperature of the etched member to form the metal component of the precursor as a film on the metal nitride on the substrate.

5. The barrier metal film production apparatus of any one ofclaims 1 to4, wherein the plasma generation means includes a coiled winding antenna disposed around the chamber.

6. The barrier metal film production apparatus of any one ofclaims 1 to4, wherein the source gas containing the halogen is the source gas containing chlorine.

7. The barrier metal film production apparatus of anyone ofclaims 1 to4, wherein the nitrogen-containing gas is a gas containing ammonia.

8. The barrier metal film production apparatus of any one ofclaims 1 to4, wherein the etched member is made of tantalum, tungsten, titanium or silicon which is a halide-forming metal.

9. A barrier metal film production method comprising:

supplying a source gas containing a halogen and a nitrogen-containing gas to an interior of a chamber between a substrate and a metallic etched member;

converting an atmosphere within the chamber into a plasma to generate a source gas plasma and a nitrogen-containing gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas, and that a metal nitride is formed upon reaction between nitrogen and the precursor; and

making a temperature of the substrate lower than a temperature of the etched member to form the metal nitride as a film on the substrate.

10. A barrier metal film production method comprising:

supplying a source gas containing a halogen and a nitrogen-containing gas to an interior of a chamber between a substrate and a metallic etched member;

converting an atmosphere within the chamber into a plasma to generate a source gas plasma and a nitrogen-containing gas plasma so that the etched member is etched with the source gas plasma to form a precursor from a metal component contained in the etched member and the source gas, and that a metal nitride is formed upon reaction between nitrogen and the precursor;

making a temperature of the substrate lower than a temperature of the etched member to form the metal nitride as a film on the substrate; and

after film formation of the metal nitride, stopping supply of the nitrogen-containing gas, and making the temperature of the substrate lower than the temperature of the etched member to form the metal component of the precursor as a film on the metal nitride on the substrate.

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