Abstract: An insulting film is modified by subjecting the insulting film to a modification treatment comprising a combination of a plasma treatment and a thermal annealing treatment. There is provided a method of enhancing the characteristic of an insulating film by improving deterioration in the characteristic of the insulating film due to carbon, a suboxide, a dangling bond or the like contained in the insulating film.

Abstract: In a process involving the formation of an insulating film on a substrate for an electronic device, the insulating film is formed on the substrate surface by carrying out two or more steps for regulating the characteristic of the insulating film involved in the process under the same operation principle. The formation of an insulating film having a high level of cleanness can be realized by carrying out treatment such as cleaning, oxidation, nitriding, and a film thickness reduction while avoiding exposure to the air. Further, carrying out various steps regarding the formation of an insulating film under the same operation principle can realize simplification of the form of an apparatus and can form an insulating film having excellent property with a high efficiency.

Abstract: In the present invention, when a gate insulation film in a DRAM is formed, an oxide film constituting a base of the gate insulation film is plasma-nitrided. The plasma nitridation is performed with microwave plasma generated by using a plane antenna having a large number of through holes. Nitrogen concentration in the gate insulation film formed by the plasma nitridation is 5 to 20% in atomic percentage. Even without subsequent annealing, it is possible to effectively prevent a boron penetration phenomenon in the DRAM and to reduce traps in the film causing deterioration in driving capability of the device.

Abstract: A Plasma processing apparatus (100) introduces microwaves into a chamber (1) by a plane antenna (31) which has a plurality of holes. A material gas, which contains a nitrogen-containing compound and a silicon-containing compound, is introduced into the chamber (1) by using the plasma processing apparatus, and plasma is generated by the microwaves. Then, a silicon nitride film is deposited by the plasma on a surface of an object to be processed. The trap density of the silicon nitride film is controlled by adjusting the conditions of the plasma CVD process.

Abstract: In a process involving the formation of an insulating film on a substrate for an electronic device, the insulating film is formed on the substrate surface by carrying out two or more steps for regulating the characteristic of the insulating film involved in the process under the same operation principle. The formation of an insulating film having a high level of cleanness can be realized by carrying out treatment such as cleaning, oxidation, nitriding, and a film thickness reduction while avoiding exposure to the air. Further, carrying out various steps regarding the formation of an insulating film under the same operation principle can realize simplification of the form of an apparatus and can form an insulating film having excellent property with a high efficiency.

Abstract: An insulting film is modified by subjecting the insulting film to a modification treatment comprising a combination of a plasma treatment and a thermal annealing treatment. There is provided a method of enhancing the characteristic of an insulating film by improving deterioration in the characteristic of the insulating film due to carbon, a suboxide, a dangling bond or the like contained in the insulating film.

Abstract: A plasma cleaning method is performed in a plasma CVD apparatus for depositing a silicon nitride film on a surface of a target substrate, and includes a stage (S1) of supplying a cleaning gas containing NF3 gas into a process container, thereby removing extraneous deposits formed on portions inside the process container; a stage (S2) of supplying a gas containing hydrogen gas into the process container and generating plasma thereof, thereby removing residual fluorine inside the process container; and a stage (S3) of supplying a gas containing a rare gas into the process container and generating plasma thereof, thereby removing residual hydrogen inside the process container.

Abstract: The surface of an insulating film disposed on an electronic device substrate is irradiated with plasma based on a process gas comprising at least an oxygen atom-containing gas, to thereby form an underlying film at the interface between the insulating film and the electronic device substrate. A good underlying film is provided at the interface between the insulating film and the electronic device substrate, so that the thus formed underlying film can improve the property of the insulating film.

Abstract: In a substrate nitriding method for nitriding a target substrate by allowing a nitrogen-containing plasma to act on silicon on a surface of the substrate in a processing chamber of a plasma processing apparatus, the nitridation by the nitrogen-containing plasma is performed by controlling a sheath voltage Vdc around the substrate to be less than or equal to about 3.5 eV. The sheath voltage Vdc is a potential difference Vp?Vf between a plasma potential Vp in a plasma generating region and a floating potential Vf of the substrate.

Abstract: Film thickness uniformity and stoichiometry are controlled and deposition rate is increased in the chemical vapor deposition (CVD) of silicon nitride from complex gas mixtures in microwave plasmas. In Si2H6+NH3+Ar gas mixtures using a radial line slot antenna (RLSA) microwave plasma to deposit SiN by CVD, deposition rate and film uniformity are improved by limiting the amounts of atomic or molecular hydrogen from the gas mixture during the deposition process. A halogen, for example, fluorine, is added to a gas mixture of silane or disilane, ammonia and argon. The halogen scavenges hydrogen from the mixture, and prevents the hydrogen from blocking the nitrogen and silicon atoms and their fragments from bonding to the surface atoms and to grow stoichiometric silicon nitride. Adding the halogen generates free halogen radicals that react with hydrogen to create hydrogen halide, for example, HF or HCl, thereby scavenging the hydrogen.

Abstract: Disclosed is a method for forming a gate insulating film comprising an oxidation step wherein a silicon oxide film is formed by having an oxygen-containing plasma act on silicon in the surface of an object to be processed in a processing chamber of a plasma processing apparatus. The processing temperature in the oxidation step is more than 600° C. and not more than 1000° C., and the oxygen-containing plasma is formed by introducing an oxygen-containing processing gas containing at least a rare gas and an oxygen gas into the process chamber while introducing a high frequency wave or microwave into the process chamber through an antenna.

Abstract: A plasma processing apparatus includes a process chamber configured to be vacuum-exhausted; a worktable configured to place a target substrate thereon inside the process chamber; a microwave generation source configured to generate microwaves; a planar antenna including a plurality of slots and configured to supply microwaves generated by the microwave generation source through the slots into the process chamber; a gas supply mechanism configured to supply a film formation source gas into the process chamber; and an RF power supply configured to apply an RF power to the worktable. The apparatus is preset to turn a nitrogen-containing gas and a silicon-containing gas supplied in the process chamber into plasma by the microwaves, and to deposit a silicon nitride film on a surface of the target substrate by use of the plasma, while applying the RF power to the worktable.

Abstract: A plasma processing apparatus generates plasma by introducing microwaves into a processing chamber by using a planar antenna having a plurality of slots. By using the plasma processing apparatus, a nitrogen containing gas and a silicon containing gas introduced into the processing chamber are brought into the plasma state, and at the time of depositing by using the plasma a silicon nitride film on the surface of the a substrate to be processed, stress to the silicon nitride film to be formed is controlled by the combination of the type and the processing pressure of the nitrogen containing gas.

Abstract: A method for forming an insulating film includes forming a silicon nitride film on a silicon surface by subjecting a target substrate wherein silicon is exposed in the surface to a treatment for nitriding the silicon, forming a silicon oxynitride film by heating the target substrate provided with the silicon nitride film in an N2O atmosphere, and nitriding the silicon oxynitride film.

Abstract: A nitriding process is performed at a process temperature of 500° C. or more by causing microwave-excited high-density plasma of a nitrogen-containing gas to act on silicon in the surface of a target object, inside a process container of a plasma processing apparatus. The plasma is generated by supplying microwaves into the process container from a planar antenna having a plurality of slots.

Abstract: A substrate processing method comprises the step of forming an oxide film on a silicon substrate surface, and introducing nitrogen atoms into the oxide film by exposing the oxide film to nitrogen radicals excited in plasma formed by a microwave introduced via a planar antenna.

Abstract: In a plasma oxidation treatment apparatus 100, dual plate structure 60 is arranged above a susceptor 2. An upper plate 61 and a lower plate 62 are made of a dielectric material such as quartz, separately arranged in parallel at a prescribed interval, for instance an interval of 5 mm, and have a plurality of through holes 61a, 62a. The two plates are arranged one over another by shifting the positions so that the through hole 62a of the lower plate 62 and the through hole 61a of the upper plate 61 are not overlapped.

Abstract: In a process involving the formation of an insulating film on a substrate for an electronic device, the insulating film is formed on the substrate surface by carrying out two or more steps for regulating the characteristic of the insulating film involved in the process under the same operation principle. The formation of an insulating film having a high level of cleanness can be realized by carrying out treatment such as cleaning, oxidation, nitriding, and a film thickness reduction while avoiding exposure to the air. Further, carrying out various steps regarding the formation of an insulating film under the same operation principle can realize simplification of the form of an apparatus and can form an insulating film having excellent property with a high efficiency.

Abstract: In a process involving the formation of an insulating film on a substrate for an electronic device, the insulating film is formed on the substrate surface by carrying out two or more steps for regulating the characteristic of the insulating film involved in the process under the same operation principle. The formation of an insulating film having a high level of cleanness can be realized by carrying out treatment such as cleaning, oxidation, nitriding, and a film thickness reduction while avoiding exposure to the air. Further, carrying out various steps regarding the formation of an insulating film under the same operation principle can realize simplification of the form of an apparatus and can form an insulating film having excellent property with a high efficiency.

Abstract: A substrate processing method comprises the step of forming an oxide film on a silicon substrate surface, and introducing nitrogen atoms into the oxide film by exposing the oxide film to nitrogen radicals excited in plasma formed by a microwave introduced via a planar antenna.