Abstract: A method of forming a single-metal film on a substrate by plasma ALD includes: contacting a surface of a substrate with a ?-diketone metal complex in a gas phase; exposing molecule-attached surface to a nitrogen-hydrogen mixed plasma; and repeating the above steps, thereby accumulating atomic layers to form a single-metal film on the substrate.

Abstract: A metal film composed of multiple atomic layers continuously formed by atomic layer deposition of Ru and Ta or Ti includes at least a top section and a bottom section, wherein an atomic composition of Ru, Ta or Ti, and N varies in a thickness direction of the metal film. The atomic composition of Ru, Ta or Ti, and N in the top section is represented as Ru(x1)Ta/Ti(y1)N(z1) wherein an atomic ratio of Ru(x1)/(Ta/Ti(y1)) is no less than 15, and z1 is 0.05 or less. The atomic composition of Ru, Ta or Ti, and N in the bottom section is represented as Ru(x2)Ta/Ti(y2)N(z2) wherein an atomic ratio of Ru(x2)/(Ta/Ti(y2)) is more than zero but less than 15, and z2 is 0.10 or greater.

Abstract: A method for forming interconnect wiring, includes: (i) covering a surface of a connection hole penetrating through interconnect dielectric layers formed on a substrate for interconnect wiring, with an underlying alloy layer selected from the group consisting of an alloy film containing ruthenium (Ru) and at least one other metal atom (M), a nitride film thereof, a carbide film thereof, and an nitride-carbide film thereof, and (ii) filling copper or a copper compound in the connection hole covered with the underlying layer.

Abstract: A method for forming a metal wiring structure includes: (i) providing a multi-layer structure including an exposed wiring layer and an exposed insulating layer in a reaction space; (ii) introducing an —NH2 or >NH terminal at least on an exposed surface of the insulating layer in a reducing atmosphere; (iii) introducing a reducing compound to the reaction space and then purging a reaction space; (iv) introducing a metal halide compound to the reaction space and then purging the reaction space; (v) introducing a gas containing N and H and then purging the reaction space; (vi) repeating steps (iii) to (v) in sequence to produce a metal-containing barrier layer; and (vii) forming a metal film on the metal-containing barrier layer.

Abstract: A method of forming a single-metal film on a substrate by plasma ALD includes: contacting a surface of a substrate with a ?-diketone metal complex in a gas phase; exposing molecule-attached surface to a nitrogen-hydrogen mixed plasma; and repeating the above steps, thereby accumulating atomic layers to form a single-metal film on the substrate.

Abstract: A metal film composed of multiple atomic layers continuously formed by atomic layer deposition of Ru and Ta or Ti includes at least a top section and a bottom section, wherein an atomic composition of Ru, Ta or Ti, and N varies in a thickness direction of the metal film. The atomic composition of Ru, Ta or Ti, and N in the top section is represented as Ru(x1)Ta/Ti(y1)N(z1) wherein an atomic ratio of Ru(x1)/(Ta/Ti(y1)) is no less than 15, and z1 is 0.05 or less. The atomic composition of Ru, Ta or Ti, and N in the bottom section is represented as Ru(x2)Ta/Ti(y2)N(z2) wherein an atomic ratio of Ru(x2)/(Ta/Ti(y2)) is more than zero but less than 15, and z2 is 0.10 or greater.

Abstract: A method of forming a Ta—Ru metal liner layer for Cu wiring includes: (i) conducting atomic deposition of Ta X times, each atomic deposition of Ta being accomplished by a pulse of hydrogen plasma, wherein X is an integer such that a surface of an underlying layer is not covered with Ta particles; (ii) after step (i), conducting atomic deposition of Ru Y times, each atomic deposition of Ru being accomplished by a pulse of hydrogen plasma, wherein Y is an integer such that the Ta particles are not covered with Ru particles; and (iii) repeating steps (i) and (ii) Z times, thereby forming a Ta—Ru metal liner layer on a Cu wiring substrate.

Abstract: A method for forming interconnect wiring, includes: (i) covering a surface of a connection hole penetrating through interconnect dielectric layers formed on a substrate for interconnect wiring, with an underlying alloy layer selected from the group consisting of an alloy film containing ruthenium (Ru) and at least one other metal atom (M), a nitride film thereof, a carbide film thereof, and an nitride-carbide film thereof, and (ii) filling copper or a copper compound in the connection hole covered with the underlying layer.

Abstract: A method of forming a Ta—Ru metal liner layer for Cu wiring includes: (i) conducting atomic deposition of Ta X times, each atomic deposition of Ta being accomplished by a pulse of hydrogen plasma, wherein X is an integer such that a surface of an underlying layer is not covered with Ta particles; (ii) after step (i), conducting atomic deposition of Ru Y times, each atomic deposition of Ru being accomplished by a pulse of hydrogen plasma, wherein Y is an integer such that the Ta particles are not covered with Ru particles; and (iii) repeating steps (i) and (ii) Z times, thereby forming a Ta—Ru metal liner layer on a Cu wiring substrate.

Abstract: A substrate processing apparatus capable of efficiently purging not only a process space but also the inside of a processing gas feed nozzle when a multi element compound film is formed on a substrate by laminating a molecular layer thereon, wherein an exhaust line is connected to one end of the processing gas feed nozzle jetting the processing gas in a laminar flow into the process space along the surface of the treated substrate, and the processing gas or purge gas is fed from the other end thereof.

Abstract: A method for depositing a thin ruthenium (Ru) film on a substrate in a reaction chamber, comprising: step (i) of supplying at least one type of gas of a ruthenium precursor being a ?-diketone-coordinated ruthenium complex and causing the gas to be adsorbed to the substrate in the reaction chamber; step (ii) of supplying a reducing gas into the reaction chamber and exciting the reducing gas, or supplying an excited reducing gas into the reaction chamber, in order to activate the ruthenium precursor adsorbed to the substrate; and step (iii) of repeating steps (i) and (ii) to form a thin ruthenium film on the substrate.

Abstract: A method to solve such a problem that plasma will not ignite in restarting operation of a processing container that has not been operated with the inside kept drawn to vacuum. Gas containing oxygen is passed in a processing container 21, and ultraviolet light is irradiated to the gas while gas inside the processing container 21 is being discharged. After that, a remote plasma source 26 is driven to ignite plasma.

Abstract: A substrate processing apparatus includes a processing vessel provided with a stage holding thereon a substrate to be processed and evacuated at an evacuation port, and a source gas supplying system that supplies plural source gases to the processing vessel separately in the form of a laminar flow, wherein the evacuation port has a slit-form shape extending in a direction generally intersecting perpendicularly to a direction of the laminar flow, the evacuation port is engaged with a valve having a valve body formed with a slit-form opening corresponding to the slit-form shape of the evacuation port, the slit-form opening being provided so as to cause a displacement with respect to the evacuation port in a direction generally intersecting perpendicularly to an extending direction of the evacuation port, the valve changing a degree of valve opening thereof via displacement of said slit-form opening.

Abstract: A method of depositing a ruthenium(Ru) thin film on a substrate in a reaction chamber, includes: (i) supplying a gas of a ruthenium precursor into the reaction chamber so that the gas of the ruthenium precursor is adsorbed onto the substrate, wherein the ruthenium precursor a ruthenium complex contains a non-cyclic dienyl; (ii) supplying an excited reducing gas into the reaction chamber to activate the ruthenium precursor adsorbed onto the substrate; and (iii) repeating steps (i) and (ii), thereby forming a ruthenium thin film on the substrate.

Abstract: A method of depositing a ruthenium(Ru) thin film on a substrate in a reaction chamber, includes: (i) supplying a gas of a ruthenium precursor into the reaction chamber so that the gas of the ruthenium precursor is adsorbed onto the substrate, wherein the ruthenium precursor a ruthenium complex contains a non-cyclic dienyl; (ii) supplying an excited reducing gas into the reaction chamber to activate the ruthenium precursor adsorbed onto the substrate; and (iii) repeating steps (i) and (ii), thereby forming a ruthenium thin film on the substrate.

Abstract: A thin-film formation apparatus possesses a reaction chamber to be evacuated, a placing portion on which a substrate is placed inside the reaction chamber, a gas-dispersion guide installed over the placing portion for supplying a gas onto a substrate surface, a gas-supply port for introducing the gas into the gas-dispersion guide, a gas-dispersion plate disposed on the side of the substrate of the gas-dispersion guide and having multiple gas-discharge pores, a first exhaust port for exhausting, downstream of the gas-dispersion plate, the gas supplied onto the substrate surface from the gas-dispersion plate, and a second exhaust port for exhausting, upstream of the gas-dispersion plate, a gas inside the gas-dispersion guide via a space between the gas-dispersion guide and the gas-dispersion plate.

Abstract: A shower head having a plurality of ejection holes for supplying an organic metal gas at uniform density to the surface of a substrate and a plurality of ejection holes for supplying an oxidizing gas at uniform density to the same is provided in a reaction furnace of an MOCVD system. A heater for heating the inside to a temperature higher than the thermal decomposition point of the organic metal gas but lower than the film forming temperature is provided in the vicinity of the substrate-side surface of the shower head.

Abstract: A method of nitriding an insulation film, includes the steps of forming nitrogen radicals by high-frequency plasma, and causing nitridation in a surface of an insulation film containing therein oxygen, by supplying the nitrogen radicals to the surface of the insulation film.

Abstract: In a cleaning step of a substrate-processing device, vacuum drawing is made for the space between an inner chamber and an outer chamber that receives the inner chamber. Temperature of the inner chamber is set higher than the temperature of the inner chamber during substrate processing and set lower than the temperature of a substrate support member. After that, a cleaning gas containing hexafluoroacetylaceton (Hhfac) is supplied in the inner chamber, and substances to be cleaned off adhering inside the inner chamber are removed.

Abstract: A method of depositing a ruthenium (Ru) thin film on a substrate includes: (i) treating a surface of the substrate with a metal-organic precursor; (ii) adsorbing a ruthenium precursor onto the treated surface of the substrate; (iii) treating the adsorbed ruthenium precursor with an excited reducing gas; and (iv) repeating steps (ii) and (iii), thereby forming a ruthenium thin film on the substrate.