Abstract: Based on designs concerning boron nitride thin-films each including boron nitride crystals in acute-ended shapes excellent in field electron emission properties, and designs of emitters adopting such thin-films, it is aimed at appropriately controlling a distribution state of such crystals to thereby provide an emitter having an excellent efficiency and thus requiring only a lower threshold electric field for electron emission. In a design of a boron nitride thin-film emitter comprising crystals that are each represented by a general formula BN, that each include sp3 bonded boron nitride, sp2 bonded boron nitride, or a mixture thereof, and that each exhibit an acute-ended shape excellent in field electron emission property; there is controlled an angle of a substrate relative to a reaction gas flow upon deposition of the emitter from a vapor phase, thereby controlling a distribution state of the crystals over a surface of the thin-film.

Abstract: In an electron emission method, a voltage is applied to a field electron emission element that has a boron nitride material containing crystal, formed on an element substrate to show a conical projection of the boron nitride material and shows a stable electron emitting property in an atmosphere when a voltage is applied thereto to emit electrons. An electron emission threshold of the field electron emission element falls due to formation of a surface electric dipolar layer by bringing it into contact with an operating atmosphere containing polar solvent gas when applying a voltage to the field electron emission element so as to emit electrons.

Abstract: A membrane body of sp3-bonded boron nitride has excellent field electron emission. The membrane body can withstand high intensity of electric field, allows the enhanced emission of electrons resulting in a high density of current, and does not degrade during long use. The membrane body includes a surface texture in a self-organized manner by vapor-phase deposition.

Abstract: The present invention provides a sp3-bonded boron nitride, represented by a general formula BN, having a hexagonal 5H or 6H polytypic form and having a property of emitting light in ultraviolet region. Its producing method comprises: introducing reaction mixed gas containing boron and nitrogen being diluted with dilution gas into a reaction chamber; and irradiating a surface of a substrate placed in the chamber, a growing surface on the substrate, and a growing spacing region about the growing surface with ultraviolet light to cause gas phase reaction, thereby generating, depositing, or growing the boron nitride on the substrate.

Abstract: There are provided an electron emission element that operates stably in the atmosphere, a method of manufacturing the same and a method of emitting field electrons using such an element as well as an emission/display device realized by using a cold cathode electron source having a surface profile showing an excellent field electron characteristic and showing a low electron emission threshold value, a high output level and a long service life. A dilute material gas of rare gas such as argon and/or helium, hydrogen or a mixture gas thereof is used. An electron emission element substrate (4) is held to a temperature level between room temperature and 1,300° C. in an atmosphere where boron source material gas and nitride source material gas are introduced to 0.0001 to 100 volume % relative to the dilute material gas under pressure of 0.

Abstract: Based on designs concerning boron nitride thin-films each including boron nitride crystals in acute-ended shapes excellent in field electron emission properties, and designs of emitters adopting such thin-films, it is aimed at appropriately controlling a distribution state of such crystals to thereby provide an emitter having an excellent efficiency and thus requiring only a lower threshold electric field for electron emission. In a design of a boron nitride thin-film emitter comprising crystals that are each represented by a general formula BN, that each include sp3 bonded boron nitride, sp2 bonded boron nitride, or a mixture thereof, and that each exhibit an acute-ended shape excellent in field electron emission property; there is controlled an angle of a substrate relative to a reaction gas flow upon deposition of the emitter from a vapor phase, thereby controlling a distribution state of the crystals over a surface of the thin-film.

Abstract: The object of the present invention is to provide a material excellent in field electron emission which can withstand the high intensity of electric field, allows the enhanced emission of electrons resulting in a high density of current, and does not degrade during long use. The solving means consists of providing a membrane body of sp3-bonded boron nitride excellent in field electron emission obtained by a method comprising the steps of introducing a reactive gas including a boron source and a nitrogen source into a reaction system; adjusting the temperature of a substrate in the reaction chamber to fall between room temperature to 1300° C.; radiating a UV beam onto the substrate with or without the concomitant existence of plasma; and forming via vapor-phase reaction a membrane on the substrate in which a surface texture allowing excellent field electron emission is formed in a self-organized manner.

Abstract: The present invention provides a sp3-bonded boron nitride, represented by a general formula BN, having a hexagonal 5H or 6H polytypic form and having a property of emitting light in ultraviolet region. Its producing method comprises: introducing reaction mixed gas containing boron and nitrogen being diluted with dilution gas into a reaction chamber; and irradiating a surface of a substrate placed in the chamber, a growing surface on the substrate, and a growing spacing region about the growing surface with ultraviolet light to cause gas phase reaction, thereby generating, depositing, or growing the boron nitride on the substrate.

Abstract: A method of making hard boron nitride by a plasma CVD method employing beam irradiation comprising the steps of: introducing a boron source gas and a nitrogen source gas into a plasma generated by employing a working gas selected from the group consisted of helium, hydrogen and a mixture of these under pressure of 0.01 through 100 torr, said boron source gas and said nitrogen source gas are provided with volumetric percent of 0.01 through 10% with respect to the working gas; transmitting activating innoculations formed in the plasma to a substrate of which temperature is maintained at 300.degree. through 1100.degree. C; converting the activating innoculations into precursor activating innoculations necessary for forming and growing a hard boron nitride film on the substrate by irradiating an ultraviolet beam to the activation innoculations on the substrate; and accumulating the hard boron nitride on the substrate.

Abstract: A method for preparing diamond or diamond-like carbon, which comprises exciting carbon by decomposing, evaporating and dissociating an organic compound or a carbon material in a combustion flame of at least 600.degree. C. of a hydrocarbon, hydrogen or a mixture thereof and oxygen gas or air, mixing thereto hydrogen in an amount of at least one time by volume the amount of carbon, and maintaining the mixture at a temperature of from 600.degree. to 1,700.degree. C. to precipitate diamond or diamond-like carbon.