Abstract: A CVD apparatus for fabricating a titanium nitride thin film is provided. The apparatus comprises an evacuatable reaction vessel having an interior, a pumping apparatus capable of exhausting the reaction vessel and maintaining the interior of the reaction vessel at a prescribed pressure, a gas feeder for introducing a mixed gas into the reaction vessel, a substrate holder in the reaction vessel for holding a substrate to be coated with a titanium nitride thin film, and a heater for heating the substrate. The gas feeder is equipped with the following components: (a) a vaporizer for vaporizing tetrakis(dialkylamino)titanium (TDAAT) from a liquid source material, (b) a first flow controller capable of setting a flow rate of the vaporized TDAAT to any level within a range of 0.

Abstract: A method of manufacturing a titanium nitride thin film at the surface of a substrate the chemical vapor deposition method (CVD method) includes supplying trakisdialkylamino titanium (TDAAT and ammonia into a reaction vessel, and heating it a prescribed temperature under a low pressure of less than 100 Pa total pressure, wherein the partial pressure PTDAAT of the source-material gas is set in a range of 0<PNH3/PTDAAT<10 with respect to the partial pressure PNH3 of the added ammonia gas.

Abstract: A method of manufacturing a titanium nitride thin film at the surface of a substrate by the chemical vapor deposition method (CVD method) includes supplying tetrakisdialkylamino titanium (TDAAT and ammonia into a reaction vessel, and heating it to a prescribed temperature under a low pressure of less than 100 Pa total pressure, wherein the partial pressure PTDAAT of the source-material gas is set in a range of 0<PNH3/PTDAAT<10 with respect to the partial pressure PNH3 of the added ammonia gas.

Abstract: A method for fabricating a titanium nitride thin film in a reaction vessel on a surface of a substrate heated to a prescribed temperature, includes the steps of mixing tetrakis(dialkylamino)titanium (TDAAT) and a first carrier gas to create a first mixed gas; feeding the first mixed gas into the reaction vessel through a first set of nozzles; mixing an added gas reactive with the tetrakis(dialkylamino)titanium with a second carrier gas to create a second mixed gas; feeding the second mixed gas into the reaction vessel through a second set of nozzles; while controlling the flow rates of the TDAAT, added gas, firt and second carrier gases; and depositing a titanium nitride thin film by the first mixed gas and the second mixed gas while confining the pressure inside the reaction vessel to a range of 0.1-15 Pa.

Abstract: A plasma enhanced CVD apparatus includes a processing chamber, a pumping system for evacuating the processing chamber, a gas inlet system for introducing a source gas, and a plasma generating electrode provided in the processing chamber for depositing a film on a substrate in the processing chamber by plasma generated by electrical power supplied to the plasma generating electrode; the plasma generating electrode has two terminals, one of the terminals is connected to a radio frequency power source and other of the terminals is grounded through an electrode potential controlling system; and the processing chamber is grounded through an inner wall potential controlling system. The present invention is further directed to a plasma enhanced CVD process, a dry etching apparatus, and a dry etch process.

Abstract: By forming at least one annular groove in each of electrical insulation members provided between a plasma generating electrode and a processing chamber, the insulation performance of the electrical insulation members are prevented from degradation during deposition of conductive films onto a substrate. The plasma generating electrode is substantially a coil of one turn and provided with a pair of introduction portions passing through a wall of the processing chamber. An insulation ring made of quartz glass is installed between each of the introduction portion and the processing chamber. The insulation ring has a round through hole in the center of a disc and three concentric protrusions, each of which is in the shape of an annulus ring, are formed at one side of the disc (the side exposed in the processing chamber). Two annular grooves are made between the protrusions. Each of the protrusions are 50 mm high, 1 mm thick, and 1 mm wide.

Abstract: A method of depositing a titanium-containing conductive thin film, which is capable of depositing a high-quality thin film having a low chlorine content by grounding, through a capacitor, a terminal of a plasma generating electrode disposed in a processing chamber. In the method, one of the introduction terminals of the plasma generating electrode is connected to a radio-frequency power source, the other terminal being grounded through the capacitor. Titanium tetrachloride, hydrogen gas, and nitrogen gas are introduced into the processing chamber at flowrates of 20 ml/min, 30 ml/min and 10 ml/min, respectively. The pressure in the processing chamber is set to about 1 Pa, and the temperature of the substrate is set to 450.degree. to 600.degree. C. A low-pressure, high-density plasma is generated with an output of the radio-frequency power source of 2.5 kW to deposit a titanium nitride film at a rate of about 30 nm/min.