An emitter includes an insulator, a pair of terminals attached to the insulator separately from each other, at least one filament attached between the pair of terminals in an arch shape, and an electron source fixed to the filament. The filament has bent portions between a contact with respect to the electron source and contacts with respect to the terminals. A device is provided with the emitter.

An electron gun EG in which mixing of secondary electrons is suppressed is provided. The electron gun EG has an electron source 1, an extraction electrode 2 for extracting an electron beam E1 from the electron source 1, and an acceleration electrode for accelerating the extracted electron beam E1. The extraction electrode 2 includes a diaphragm 4 for allowing a part of the electron beam E1 to pass through, a shield 5 positioned above the diaphragm 4 apart from the diaphragm 4, and a shield 6 positioned below the diaphragm 4 apart from the diaphragm 4. The diaphragm 4 has an opening OP4 having an opening diameter D4, the shield 5 has an opening OP5 having an opening diameter D5 which is greater than the opening diameter D4, and the shield 6 has an opening OP6 having an opening diameter D6 which is greater than the opening diameter D4.

Provided is a high-brightness, high-current electron source including a wire-like member. The wire-like member has an electron emission plane at the tip of the wire-like member. The electron emission plane has a projectingly curved surface. At least the surface of the electron emission plane is formed of an amorphous material.

Electron emitters and methods of fabricating the electron emitters are disclosed. According to certain embodiments, an electron emitter includes a tip with a planar region having a diameter in a range of approximately (0.05-10) micrometers. The electron emitter tip is configured to release field emission electrons. The electron emitter further includes a work-function-lowering material coated on the tip.

Provided are a charged particle gun and a charged particle beam apparatus that can reduce instability in the amount of emitted charged particles and deviation in the charged particle trajectory when the amount of charged particle beams is increased. A charged particle gun includes a charged particle source that generates a charged particle, an electrode portion that includes an extraction electrode for extracting a charged particle beam from the charged particle source, a voltage introduction unit that introduces voltage to the electrode portion, and a temperature adjustment unit that adjusts a temperature of the electrode portion. The temperature adjustment unit is configured to adjust the temperature of the electrode portion based on a change in a state of the electrode portion.

A charged particle microscope and a method of operating a charged particle microscope are disclosed. The microscope employs a source for producing charged particles, and a source lens below the source to form a charged particle beam which is directed onto a specimen by a condenser system. A detector collects radiation emanating from the specimen in response to irradiation of the specimen by the beam. The source lens is a compound lens, focusing the beam within a vacuum enclosure using both a magnetic lens having permanent magnets outside the enclosure to produce a magnetic field at the beam, and a variable electrostatic lens within the enclosure.

A magnetic gun lens and an electrostatic gun lens can be used in an electron beam apparatus and can help provide high resolutions for all usable electron beam currents in scanning electron microscope, review, and/or inspection uses. An extracted beam can be directed at a wafer through a beam limiting aperture using the magnetic gun lens. The electron beam also can pass through an electrostatic gun lens after the electron beam passes through the beam limiting aperture.

A conventional method to process a tip fails to designate the dimension of the shape of the end of the tip, and so fails to obtain a tip having any desired diameter. Impurities may be attached to the tip. Based on a correlation between the voltage applied or the time during processing of the end of the tip and the diameter of the tip end, the applied voltage is controlled so as to obtain a desired diameter of the tip end for processing of the tip. This allows a sharpened tip made of a tungsten monocrystal thin wire to be manufactured to have any desired diameter in the range of 0.1 ?m or more and 2.0 ?m or less.

An emitter includes an insulator, a pair of terminals attached to the insulator separately from each other, at least one filament attached between the pair of terminals in an arch shape, and an electron source fixed to the filament. The filament has bent portions between a contact with respect to the electron source and contacts with respect to the terminals. A device is provided with the emitter.

A manufacturing method for an electron source according to the present disclosure includes steps of: (A) cutting out a chip from a block of an electron emission material, (B) fixing a first end portion of the chip to a distal end of a support needle, and (C) sharpening a second end portion of the chip. The step (A) includes forming first and second grooves which constitute first and second surfaces of the chip in the block by irradiating a surface of the block with an ion beam. The first end portion of the chip includes the first surface and the second surface with the surfaces forming an angle of 10 to 90. The step (B) includes forming a joint between the distal end of the support needle and the first end portion of the chip.