Abstract: A method of producing a composite nanoparticle (M-AxOy), having: generating, in an inert gas, an alloy (A-M) nanoparticle, which contains 0.1 at. % to 30 at. % of a noble metal (M), with the balance being a base metal (A) and inevitable impurities, and which has a particle size of 1 nm to 100 nm, to heat the alloy (A-M) nanoparticle and to bring the alloy (A-M) nanoparticle into contact with a supplied oxidizing gas during transportation of the alloy (A-M) nanoparticle with the inert gas, to oxidize the base metal component (A) in the floating alloy (A-M) nanoparticle, and to phase separate into the thus-oxidized base metal component (AxOy) and the noble metal component (M), to thereby obtain a composite nanoparticle (M-AxOy) having one noble metal particle (M) combined to the surface of a particulate base metal oxide (AxOy).

Abstract: A method of producing a composite nanoparticle (M-AxOy), having: generating, in an inert gas, an alloy (A-M) nanoparticle, which contains 0.1 at. % to 30 at. % of a noble metal (M), with the balance being a base metal (A) and inevitable impurities, and which has a particle size of 1 nm to 100 nm, to heat the alloy (A-M) nanoparticle and to bring the alloy (A-M) nanoparticle into contact with a supplied oxidizing gas during transportation of the alloy (A-M) nanoparticle with the inert gas, to oxidize the base metal component (A) in the floating alloy (A-M) nanoparticle, and to phase separate into the thus-oxidized base metal component (AxOy) and the noble metal component (M), to thereby obtain a composite nanoparticle (M-AxOy) having one noble metal particle (M) combined to the surface of a particulate base metal oxide (AxOy).

Abstract: Provided is a method of fabricating, with satisfactory adhesion, a thin film of a metal or a metallic-compound, such as a metal oxide or nitride, on a substrate made of a high-melting-point material such as silicon or ceramics by using a metal or metallic-compound target as the primary raw material so as to eliminate the necessity of using harmful gases such as organometallic gas, and by using an atmospheric-pressure plasma generated under atmospheric pressure as a reaction field and also as a heat source. Additionally provided is an apparatus for fabricating the thin film.

Abstract: Provided are a method and a device for producing nanoparticles of a low melting point material such as gold at more than 10 times faster the rate of conventional technology while maintaining the time-averaged temperature of pulse-modulated atmospheric-pressure plasma at a temperature that is low enough so as not to damage a heat-sensitive material disposed downstream. This method of preparing nanoparticles of a low melting point inorganic material in which a wire made of a low melting point inorganic material is inserted into a plasma-generating capillary tube or a plasma-generating nozzle and atmospheric-pressure high frequency plasma is generated in the capillary tube or nozzle is characterized by generating the plasma by applying a high frequency voltage possessing a waveform which exhibits its maximum value when it rises and then immediately falls, and which is pulse-modulated so that the duty ratio thereof is 10% or less.

Abstract: Provided is a method of fabricating, with satisfactory adhesion, a thin film of a metal or a metallic-compound, such as a metal oxide or nitride, on a substrate made of a high-melting-point material such as silicon or ceramics by using a metal or metallic-compound target as the primary raw material so as to eliminate the necessity of using harmful gases such as organometallic gas, and by using an atmospheric-pressure plasma generated under atmospheric pressure as a reaction field and also as a heat source. Additionally provided is an apparatus for fabricating the thin film.

Abstract: Proposed are molybdenum or tungsten particles having a stable face-centered cubic structure of molybdenum and tungsten belonging to a VI group in a periodic table or a thin film formed from the foregoing particles, and a manufacturing method thereof. Specifically, provided are molybdenum or tungsten particles having a face-centered cubic (fcc) crystal structure or a thin film formed from the foregoing particles, wherein the particles have a large-diameter particle structure that is thermodynamically stable or metastable; and molybdenum or tungsten particles having a face-centered cubic (fcc) crystal structure or a thin film formed from the foregoing particles, wherein the particles have a pentagonal and star-shaped particle structure.

Abstract: Provided are a method and a device for producing nanoparticles of a low melting point material such as gold at more than 10 times faster the rate of conventional technology while maintaining the time-averaged temperature of pulse-modulated atmospheric-pressure plasma at a temperature that is low enough so as not to damage a heat-sensitive material disposed downstream. This method of preparing nanoparticles of a low melting point inorganic material in which a wire made of a low melting point inorganic material is inserted into a plasma-generating capillary tube or a plasma-generating nozzle and atmospheric-pressure high frequency plasma is generated in the capillary tube or nozzle is characterized by generating the plasma by applying a high frequency voltage possessing a waveform which exhibits its maximum value when it rises and then immediately falls, and which is pulse-modulated so that the duty ratio thereof is 10% or less.

Abstract: Proposed are molybdenum or tungsten particles having a stable face-centered cubic structure of molybdenum and tungsten belonging to a VI group in a periodic table or a thin film formed from the foregoing particles, and a manufacturing method thereof. Specifically, provided are molybdenum or tungsten particles having a face-centered cubic (fcc) crystal structure or a thin film formed from the foregoing particles, wherein the particles have a large-diameter particle structure that is thermodynamically stable or metastable; and molybdenum or tungsten particles having a face-centered cubic (fcc) crystal structure or a thin film formed from the foregoing particles, wherein the particles have a pentagonal and star-shaped particle structure.