Abstract: A focused ion beam system includes a gas ion source and an emitter structure. The emitter structure includes a pair of conductive pins fixed to a base member, a filament connected between the pair of conductive pins, and an emitter which has a tip end with one atom or three atoms and which is connected to the filament. A supporting member is fixed to the base material, and the emitter is connected to the supporting member.

Abstract: A focused ion beam apparatus includes an ion source that emits an ion beam, an extraction electrode that extracts ions from a tip end of an emitter of the ion source, and a first lens electrode that configures a condenser lens by a potential difference with the extraction electrode, the condenser lens focusing the ions extracted by the extraction electrode, in which a strong lens action is generated between the extraction electrode and the first lens electrode so as to focus all ions extracted from the ion source to pass through a hole of the condenser lens including the first lens electrode.

Abstract: There is provided an iridium tip including a pyramid structure having one {100} crystal plane as one of a plurality of pyramid surfaces in a sharpened apex portion of a single crystal with <210> orientation. The iridium tip is applied to a gas field ion source or an electron source. The gas field ion source and/or the electron source is applied to a focused ion beam apparatus, an electron microscope, an electron beam applied analysis apparatus, an ion-electron multi-beam apparatus, a scanning probe microscope or a mask repair apparatus.

Abstract: There is provided a repair apparatus including a gas field ion source which includes an ion generation section including a sharpened tip, a cooling unit which cools the tip, an ion beam column which forms a focused ion beam by focusing ions of a gas generated in the gas field ion source, a sample stage which moves while a sample to be irradiated with the focused ion beam is placed thereon, a sample chamber which accommodates at least the sample stage therein, and a control unit which repairs a mask or a mold for nano-imprint lithography, which is the sample, with the focused ion beam formed by the ion beam column. The gas field ion source generates nitrogen ions as the ions, and the tip is constituted by an iridium single crystal capable of generating the ions.

Abstract: A plasma ion source includes: a gas introduction chamber, into which raw gas is introduced; an insulation member provided in the gas introduction chamber; a plasma generation chamber connected to the gas introduction chamber; a coil that is wound along an outer circumference of the plasma generation chamber and to which high-frequency power is applied; and an electrode arranged at a boundary between the gas introduction chamber and the plasma generation chamber and having a plurality of through-holes formed therein, wherein a size of the through-holes is smaller than a length of a plasma sheath.

Abstract: A plasma ion source includes: a gas introduction chamber, into which raw gas is introduced; a plasma generation chamber connected to the gas introduction chamber and made of a dielectric material; a coil wound along an outer circumference of the plasma generation chamber and to which high-frequency power is applied; an envelope surrounding the gas introduction chamber, the plasma generation chamber and the coil; and insulating liquid filled inside the gas introduction chamber, the plasma generation chamber and the envelope to immerse the coil and having an dielectric strength voltage relatively greater than that of the envelope and the same dielectric dissipation factor as the plasma generation chamber.

Abstract: A focused ion beam apparatus has an emitter for emitting an ion beam, an ion source chamber accommodating the emitter, a cooling unit and a heating unit for cooling and heating, respectively, the emitter, and an ion source gas supply section for supplying to the ion source chamber an ion source gas that is exchangeable with another ion source gas. A control section controls an operation of the cooling unit such that a temperature of a wall surface contacting the ion source gas in the ion source chamber is maintained at a temperature higher than a temperature at which the ion source gas before and after the exchange freezes. The control section controls an operation of the heater so that the emitter is temporarily heated to release the ion source gas from a surface of the emitter before the ion source gas is exchanged with the other ion source gas.

Abstract: Disclosed herein is a focused ion beam apparatus equipped with a gas field ion source that can produce a focused ion beam for a long period of time by stably and continuously emitting ions from the gas field ion source having high luminance, along an optical axis of an ion-optical system for a long period of time. In the focused ion beam apparatus equipped with a gas field ion source having an emitter for emitting ions, the emitter has a shape in which sharpened iridium is fixed to dissimilar wire.

Abstract: There is provided a repair apparatus including a gas field ion source which includes an ion generation section including a sharpened tip, a cooling unit which cools the tip, an ion beam column which forms a focused ion beam by focusing ions of a gas generated in the gas field ion source, a sample stage which moves while a sample to be irradiated with the focused ion beam is placed thereon, a sample chamber which accommodates at least the sample stage therein, and a control unit which repairs a mask or a mold for nano-imprint lithography, which is the sample, with the focused ion beam formed by the ion beam column. The gas field ion source generates nitrogen ions as the ions, and the tip is constituted by an iridium single crystal capable of generating the ions.

Abstract: A focused ion beam apparatus has an ion source chamber in which is disposed an emitter for emitting ions. The surface of the emitter is formed of a precious metal, such as platinum, palladium, iridium, rhodium or gold. A gas supply unit supplies nitrogen gas to the ion source chamber so that the nitrogen gas adsorbs on the surface of the emitter. An extracting electrode is spaced from the emitter, and a voltage is applied to the extracting electrode to ionize the adsorbed nitrogen gas and extract nitrogen ions in the form of an ion beam. A temperature control unit controls the temperature of the emitter.

Abstract: A focused ion beam system includes a gas field ion source which generates gas ions, an ion gun unit which accelerates the gas ions and radiates the gas ions as an ion beam, a beam optical system which includes at least a focusing lens electrode and radiates the ion beam onto a sample, and an image acquiring mechanism which acquires an FIM image of a tip of an emitter based on the ion beam. The image acquiring mechanism includes an alignment electrode which is disposed between the ion gun unit and the focusing lens electrode and adjusts a radiation direction of the ion beam, an alignment control unit which applies an alignment voltage to the alignment electrode, and an image processing unit which combines a plurality of FIM images acquired when applying different alignment voltages to generate one composite FIM image.

Abstract: A focused ion beam system includes a gas ion source and an emitter structure. The emitter structure includes a pair of conductive pins fixed to a base member, a filament connected between the pair of conductive pins, and an emitter which has a tip end with one atom or three atoms and which is connected to the filament. A supporting member is fixed to the base material, and the emitter is connected to the supporting member.

Abstract: There is provided an emitter structure, a gas ion source including the emitter structure, and a focused ion beam system including the gas ion source. The emitter structure includes a pair of conductive pins which are fixed to a base member, a filament which is connected between the pair of conductive pins, and an emitter which is connected to the filament and has a sharp tip. A supporting member is fixed to the base material, and the emitter is connected to the supporting member.

Abstract: An ion beam apparatus includes an ion source configured to emit an ion beam, a condenser lens electrode that condenses the ion beam, and a condenser lens power source configured to apply a voltage to the condenser lens electrode. A storage portion stores a first voltage value, a second voltage value, a third voltage value, and a fourth voltage value. A control portion retrieves the third voltage value from the storage portion and sets the retrieved third voltage value to the condenser lens power source when an observation mode is switched to a wide-range observation mode, and retrieves the fourth voltage value from the storage portion and sets the retrieved fourth voltage value to the condenser lens power source when a processing mode is switched to the wide-range observation mode.

Abstract: A focused ion beam apparatus has an ion source chamber in which is disposed an emitter for emitting ions. The surface of the emitter is formed of a precious metal, such as platinum, palladium, iridium, rhodium or gold. A gas supply unit supplies nitrogen gas to the ion source chamber so that the nitrogen gas adsorbs on the surface of the emitter. An extracting electrode is spaced from the emitter, and a voltage is applied to the extracting electrode to ionize the adsorbed nitrogen gas and extract nitrogen ions in the form of an ion beam. A temperature control unit controls the temperature of the emitter.

Abstract: A method for fabricating a sharpened needle-like emitter, the method including: electrolytically polishing an end portion of an electrically conductive emitter material so as to be tapered toward a tip portion thereof; performing a first etching in which the electrolytically polished part of the emitter material is irradiated with a charged-particle beam to form a pyramid-like sharpened part having a vertex including the tip portion; performing a second etching in which the tip portion is further sharpened through field-assisted gas etching, while observing a crystal structure at the tip portion by a field ion microscope and keeping the number of atoms at a leading edge of the tip portion at a predetermined number or less; and heating the emitter material to arrange the atoms at the leading edge of the tip portion of the sharpened part in a pyramid shape.

Abstract: There is provided a repair apparatus including a gas field ion source which includes an ion generation section including a sharpened tip, a cooling unit which cools the tip, an ion beam column which forms a focused ion beam by focusing ions of a gas generated in the gas field ion source, a sample stage which moves while a sample to be irradiated with the focused ion beam is placed thereon, a sample chamber which accommodates at least the sample stage therein, and a control unit which repairs a mask or a mold for nano-imprint lithography, which is the sample, with the focused ion beam formed by the ion beam column. The gas field ion source generates nitrogen ions as the ions, and the tip is constituted by an iridium single crystal capable of generating the ions.

Abstract: A focused ion beam apparatus has an ion source chamber in which is disposed an emitter for emitting ions. A gas supply unit supplies nitrogen gas to the ion source chamber so that the nitrogen gas adsorbs on the surface of the emitter, and the gas supply unit maintains the pressure in the ion source chamber in the range 1.0×10?6 Pa to 1.0×10?2 Pa. An extracting electrode is spaced from the emitter, and a voltage is applied to the extracting electrode to ionize the adsorbed nitrogen gas and extract nitrogen ions in the form of an ion beam. A temperature control unit controls the temperature of the emitter.

Abstract: There is provided an iridium tip including a pyramid structure having one {100} crystal plane as one of a plurality of pyramid surfaces in a sharpened apex portion of a single crystal with <210> orientation. The iridium tip is applied to a gas field ion source or an electron source. The gas field ion source and/or the electron source is applied to a focused ion beam apparatus, an electron microscope, an electron beam applied analysis apparatus, an ion-electron multi-beam apparatus, a scanning probe microscope or a mask repair apparatus.

Abstract: A focused ion beam apparatus is configured to perform at least one of a process of controlling an operation of a cooling unit so that a temperature of a wall surface contacting a source gas in an ion source chamber is maintained at a temperature higher than a temperature at which the source gas freezes and a process of controlling an operation of a heater so that an emitter is temporarily heated when the source gas is exchanged.