Abstract: An activation mechanism is provided in an activation region of an electron gun, and includes a light source device 3 configured to irradiate a photocathode with excitation light, a heat generating element, an oxygen generation unit configured to generate oxygen by heating the heat generating element, and an emission current meter configured to monitor an emission current generated by electron emission when the photocathode 1 is irradiated with the excitation light from the light source device. In a surface activation process, the photocathode is irradiated with the excitation light from the light source device, an emission current amount of the photocathode is monitored by the emission current meter, the heat generating element is heated to generate oxygen by the oxygen generation unit, and the heating of the heat generating element is stopped when the emission current amount of the photocathode satisfies a predetermined stop criterion.

Abstract: Provided is an electron microscope for generating an observation image of a sample by using an electron beam in order to obtain a scanning electron microscope image by low angle backscattered electrons, which are backscattered electrons emitted at a low angle with respect to a sample surface, even for an electron microscope including an objective lens that leaks a magnetic field to a sample.

Abstract: To provide an ion milling apparatus adapted to suppress the contamination of a beam forming electrode. The ion milling apparatus includes: an ion gun containing therein a beam forming electrode for forming an ion beam; a specimen holder for fixing a specimen to be processed by irradiation of an ion beam; a mask for shielding a part of the specimen from the ion beam; and an ion gun controller for controlling the ion gun.

Abstract: To provide an ion gun of a penning discharge type capable of achieving a milling rate which is remarkably higher than that in the related art, an ion milling device including the same, and an ion milling method. An ion generation unit includes a cathode that emits electrons, an anode that is provided within the ion generation unit and has an inner diameter of 5.2 mm or less, and magnetic-field generation means using a permanent magnet of which a maximum energy product ranges from 110 kJ/m3 to 191 kJ/m3.

Abstract: To provide an ion milling apparatus adapted to suppress the contamination of a beam forming electrode. The ion milling apparatus includes: an ion gun containing therein a beam forming electrode for forming an ion beam; a specimen holder for fixing a specimen to be processed by irradiation of an ion beam; a mask for shielding a part of the specimen from the ion beam; and an ion gun controller for controlling the ion gun.

Abstract: An H3+ ion is used as an ion beam to achieve improvement in focusing capability influencing observed resolution and machining width, improvement in the beam stability, and a reduction in damage to the sample surface during the beam irradiation, in the process of observation and machining of the sample surface by the ion beam. The H3+ ion can be obtained by use of a probe current within a voltage range 21 around a second peak 23 occurring when an extracted voltage is applied to a needle-shaped emitter tip with an apex terminated by three atoms or less, in an atmosphere of hydrogen gas.

Abstract: An ion beam device according to the present invention suppresses the fluctuation of an ion emission current by cleaning the inside of a chamber without entailing wear damage to an emitter electrode. The ion beam device includes a GFIS including an emitter electrode having a needle-shaped tip; an extraction electrode having an opening at a position spaced apart from the tip of the emitter electrode; and a chamber encapsulating the emitter electrode therein. The GFIS includes an ionizable gas introduction path for introducing an ionizable gas into the chamber in a state where a voltage equal to or more than a beam generating voltage is applied to the emitter electrode; and a cleaning gas introduction path for introducing a cleaning gas into the chamber in either a state where a voltage less than the beam generating voltage is applied to the emitter electrode or a state where no voltage is applied to the emitter electrode.

Abstract: An ion beam device according to the present invention suppresses the fluctuation of an ion emission current by cleaning the inside of a chamber without entailing wear damage to an emitter electrode. The ion beam device includes a GFIS including an emitter electrode having a needle-shaped tip; an extraction electrode having an opening at a position spaced apart from the tip of the emitter electrode; and a chamber encapsulating the emitter electrode therein. The GFIS includes an ionizable gas introduction path for introducing an ionizable gas into the chamber in a state where a voltage equal to or more than a beam generating voltage is applied to the emitter electrode; and a cleaning gas introduction path for introducing a cleaning gas into the chamber in either a state where a voltage less than the beam generating voltage is applied to the emitter electrode or a state where no voltage is applied to the emitter electrode.

Abstract: The invention is to reduce non-uniformity of a processing shape over a wide range of a single field-of-view. The invention is directed to a method of processing micro electro mechanical systems with a first step and a second step in a processing apparatus including an irradiation unit that irradiates a sample with a charged particle beam, a shape measuring unit that measures a shape of the sample, and a control unit. In the first step, the irradiation unit irradiates a plurality of single field-of-view points with the charged particle beam in a first region of the sample, the shape measuring unit measures the shape of a spot hole formed in the first region of the sample, and the control unit sets, based on measurement results of the shape of the spot hole, a scan condition of the charged particle beam or a forming mask of the charged particle beam at each of the single field-of-view points.

Abstract: According to an embodiment of the present invention, an ion beam apparatus switches between an operation mode of performing irradiation with an ion beam most including H3+ ions and an operation mode of performing irradiation with an ion beam most including ions heavier than the H3+.

Abstract: In order to provide an ion beam apparatus excellent in safety and stability even when a sample is irradiated with hydrogen ions, the ion beam apparatus includes a vacuum chamber, a gas field ion source that is installed in the vacuum chamber and has an emitter tip, and gas supply means for supplying a gas to the emitter tip. The gas supply means includes a mixed gas chamber that is filled with a hydrogen gas and a gas for diluting the hydrogen gas below an explosive lower limit.

Abstract: A sufficient processing speed and sufficient processing accuracy are obtained in a microstructure manufacturing method using ion beams. The microstructure manufacturing method includes the steps of: (a) irradiating a first region of a sample with a first ion beam (projection ion beam) formed by being passed through a first opening portion of a first mask, and etching the sample; and (b) irradiating a second region that is wider than the first region in a direction along a beam width, with a second ion beam (projection ion beam), and processing the sample. Furthermore, a magnitude of a skirt width of a longitudinal section of the second ion beam is smaller than a magnitude of a skirt width of a longitudinal section of the first ion beam.

Abstract: The present invention provides a technology for avoiding radiation of an ion beam at a position other than a desired processing position. A microstructure manufacturing method includes a step of radiating an ion beam to a sample; a step of supplying a gas to the sample; a step of stopping supplying the gas to the sample; and a step of stopping radiating the ion beam to the sample. The step of radiating the ion beam is performed earlier than the step of supplying the gas or the step of stopping supplying the gas is performed earlier than the step of stopping radiating the ion beam.

Abstract: In order to provide an ion beam apparatus excellent in safety and stability even when a sample is irradiated with hydrogen ions, the ion beam apparatus includes a vacuum chamber, a gas field ion source that is installed in the vacuum chamber and has an emitter tip, and gas supply means for supplying a gas to the emitter tip. The gas supply means includes a mixed gas chamber that is filled with a hydrogen gas and a gas for diluting the hydrogen gas below an explosive lower limit.

Abstract: To provide an ion gun of a penning discharge type capable of achieving a milling rate which is remarkably higher than that in the related art, an ion milling device including the same, and an ion milling method. An ion generation unit includes a cathode that emits electrons, an anode that is provided within the ion generation unit and has an inner diameter of 5.2 mm or less, and magnetic-field generation means using a permanent magnet of which a maximum energy product ranges from 110 kJ/m3 to 191 kJ/m3.

Abstract: In order to provide an ion beam apparatus excellent in safety and stability even when a sample is irradiated with hydrogen ions, the ion beam apparatus includes a vacuum chamber, a gas field ion source that is installed in the vacuum chamber and has an emitter tip, and gas supply means for supplying a gas to the emitter tip. The gas supply means includes a mixed gas chamber that is filled with a hydrogen gas and a gas for diluting the hydrogen gas below an explosive lower limit.

Abstract: To provide an ion milling system that can suppress an orbital shift of an observation electron beam emitted from an electron microscope column, the ion milling system includes: a Penning discharge type ion gun 100 that includes a permanent magnet 114 and that generates ions for processing a sample; and a scanning electron microscope for observing the sample, in which a magnetic shield 172 for reducing a leakage magnetic field from the permanent magnet 114 to the electron microscope column is provided.

Abstract: Since a diffraction phenomenon occurs in the electron beam passing through a differential evacuation hole, an electron beam whose probe diameter is narrowed cannot pass through a hole having an aspect ratio of a predetermined value or more, and accordingly, a degree in vacuum on the electron beam side cannot be improved. By providing a differential evacuation hole with a high aspect ratio in an ion beam device, it becomes possible to obtain an observed image on a sample surface, with the sample being placed under the atmospheric pressure or a pressure similar thereto, in a state where the degree of vacuum on the ion beam side is stabilized. Moreover, by processing the differential evacuation hole by using an ion beam each time it is applied, both a normal image observation with high resolution and an image observation under atmospheric pressure or a pressure similar thereto can be carried out.

Abstract: To provide an ion gun of a penning discharge type capable of narrowing a beam with a low ion beam current at a low acceleration voltage, an ion milling device including the same, and an ion milling method. An ion milling device that controls half width of a beam profile of an ion beam with which a sample is irradiated from an ion gun to be in a range of 200 ?m to 350 ?m. The device includes: the ion gun that ionizes a gas supplied from the outside, and emits an ion beam; a gas-flow-rate varying unit that varies a flow rate of the gas supplied to the ion gun; and a current measurement unit that measures a current value of the ion beam emitted from the ion gun. The gas-flow-rate varying unit sets a gas flow rate to be higher than a gas flow rate at which the ion beam current has a maximum value based on the current value measured by the current measurement unit and the flow rate of the gas determined by the gas-flow-rate varying unit.

Abstract: To provide an ion gun of a penning discharge type capable of achieving a milling rate which is remarkably higher than that in the related art, an ion milling device including the same, and an ion milling method. An ion generation unit includes a cathode that emits electrons, an anode that is provided within the ion generation unit and has an inner diameter of 5.2 mm or less, and magnetic-field generation means using a permanent magnet of which a maximum energy product ranges from 110 kJ/m3 to 191 kJ/m3.