An ion generator includes an arc chamber defining a plasma generation space, and a cathode which emits thermoelectrons toward the plasma generation space. The arc chamber includes a box-shaped main body having an opening, and a slit member mounted to cover the opening and provided with a front slit. An inner surface of the main body is exposed to the plasma generation space made of a refractory metal material. The slit member includes an inner member made of graphite and an outer member made of another refractory metal material. The outer member includes an outer surface exposed to an outside of the arc chamber. The inner member includes an inner surface exposed to the plasma generation space, and an opening portion which forms the front slit extending from the inner surface of the inner member to the outer surface of the outer member.

A charged-particle beam apparatus is provided with a cathode to emit charged particle beams, an anode to propagate the charged particle beams emitted from the cathode in a sample surface direction, an aperture to propagate a charged particle beam passing through an opening at a predetermined position and of a predetermined shape, among the charged particle beams passing through the anode, in the sample surface direction, and a first electrode that is disposed between the anode and the aperture, and is set at a first electric potential of a polarity repelling a polarity of an ion generated due to collision of a charged particle beam.

A charged-particle beam apparatus is provided with a cathode to emit charged particle beams, an anode to propagate the charged particle beams emitted from the cathode in a sample surface direction, an aperture to propagate a charged particle beam passing through an opening at a predetermined position and of a predetermined shape, among the charged particle beams passing through the anode, in the sample surface direction, and a first electrode that is disposed between the anode and the aperture, and is set at a first electric potential of a polarity repelling a polarity of an ion generated due to collision of a charged particle beam.

An electron beam generator, a plasma processing apparatus, and a plasma processing method, the electron beam generator including a side insulator configured to surround the substrate support, the side insulator having an electron beam chamber therein; a first electrode embedded in the side insulator and adjacent to a first side wall of the electron beam chamber; a second electrode on a second side wall of the electron beam chamber; and a guide in an outlet of the electron beam chamber, the guide including slits through which electron beams generated in the electron beam chamber are transmittable into the process chamber.

An electron beam generator, a plasma processing apparatus, and a plasma processing method, the electron beam generator including a side insulator configured to surround the substrate support, the side insulator having an electron beam chamber therein; a first electrode embedded in the side insulator and adjacent to a first side wall of the electron beam chamber; a second electrode on a second side wall of the electron beam chamber; and a guide in an outlet of the electron beam chamber, the guide including slits through which electron beams generated in the electron beam chamber are transmittable into the process chamber.

An apparatus for generating electron radiation comprises a wire-shaped hot cathode that is much more extensive in a longitudinal direction than in a transverse direction. Electron radiation emerges from the hot cathode that, due to the elongated shape of the hot cathode, exhibits an elongated, line-shaped cross section perpendicular to its direction of propagation, where the extension in longitudinal direction of the line is significantly greater than in transverse direction of the line. The apparatus further comprises a cathode electrode and an anode. A voltage for accelerating the electrons emitted from the hot cathode is applied between the cathode electrode and the anode. The hot cathode is arranged to be spaced apart from the cathode electrode such that electrons that are accelerated to the anode are emitted from the hot cathode in each of the transverse directions.

A beam arrangement portion is provided to arrange multiple primary electron beams on a substrate. The beam arrangement portion arranges the multiple primary electron beams in a square lattice along a first moving direction of a stage allowing the substrate to be placed thereon and a second moving direction perpendicular to the first moving direction in a state where, when the multiple primary electron beams are viewed as a whole, beams around four corners of the square lattice are omitted.

A beam arrangement portion is provided to arrange multiple primary electron beams on a substrate. The beam arrangement portion arranges the multiple primary electron beams in a square lattice along a first moving direction of a stage allowing the substrate to be placed thereon and a second moving direction perpendicular to the first moving direction in a state where, when the multiple primary electron beams are viewed as a whole, beams around four corners of the square lattice are omitted.

An apparatus includes: a structure having a lumen for accommodating a beam (e.g., electron beam, proton beam, or a charged particle beam), wherein the structure is a component of a medical radiation machine having a target for interaction with the beam to generate radiation; and a first beam position monitor comprising a first electrode and a second electrode, the first electrode being mounted to a first side of the structure, the second electrode being mounted to a second side of the structure, the second side being opposite from the first side; wherein the first beam position monitor is located upstream with respect to the target.

An apparatus includes: a structure having a lumen for accommodating a beam (e.g., electron beam, proton beam, or a charged particle beam), wherein the structure is a component of a medical radiation machine having a target for interaction with the beam to generate radiation; and a first beam position monitor comprising a first electrode and a second electrode, the first electrode being mounted to a first side of the structure, the second electrode being mounted to a second side of the structure, the second side being opposite from the first side; wherein the first beam position monitor is located upstream with respect to the target.