An ion implanter includes: a main body which includes a plurality of units which are disposed along a beamline along which an ion beam is transported, and a substrate transferring/processing unit which is disposed farthest downstream of the beamline, and has a neutron ray source in which a neutron ray is generated due to collision of a ultrahigh energy ion beam; an enclosure which at least partially encloses the main body; and a neutron ray scattering member which is disposed at a position where a neutron ray which is emitted from the neutron ray source is incident in a direction in which a distance from the neutron ray source to the enclosure is equal to or less than a predetermined value.

An x-ray shield for improved vacuum conductivity is disclosed herein. An example x-ray shield includes at least one elongate member formed from high atomic weight material shaped into a twist with at least 180 of twist.

An x-ray shield for improved vacuum conductivity is disclosed herein. An example x-ray shield includes at least one elongate member formed from high atomic weight material shaped into a twist with at least 180 of twist.

A nozzle-type electron beam irradiation device includes a vacuum chamber, an electron beam generator disposed in the vacuum chamber, and a vacuum nozzle that is connected to the vacuum chamber so as to guide an electron beam from the electron beam generator and emit the electron beam to the outside. The nozzle-type electron beam irradiation device includes a high-vacuum pump capable of sucking gas from the vicinity of the connecting part of the vacuum nozzle in the vacuum chamber.

A vacuum apparatus according to an embodiment includes a chamber configured air-tightly, a vacuum pump configured to exhaust gas from the chamber, and an exhaustion structure placed between the chamber and an inlet port of the vacuum pump and having a ventilation path surrounded by a wall of the exhaustion structure. The vacuum pump exhausts gas from the chamber through the ventilation path of the exhaustion structure. A layer of thermal energy absorbing material is formed on at least part of an inner surface of the wall of the exhaustion structure to absorb energy of thermal radiation emitted from the inlet port of the vacuum pump.

Methods and apparatus are disclosed for providing an X-ray shield within an ultra-high vacuum enclosure. A shell is fabricated, leak-tested, filled with an X-ray shielding material, and sealed. An elongated twisted X-ray shield can be deployed within a pump-out channel of an electron microscope or similar equipment. The shield can incorporate lead within a stainless steel shell, with optional low-Z cladding outside the shell. Further variations are disclosed.

The improved cathode sub-assembly includes a solid cylindrical cathode of tungsten, a cylindrical holder concentric to the cathode with an internal radially directed rib receiving one end of the cathode, and a cylindrical reflector threadably mounted within the holder in circumferentially spaced relation to the cathode. The holder is threadably mounted in a support plate to be able to be readily removed for servicing and/or replacement.

A transmission-target x-ray tube can include an x-ray window mounted on a window-housing. The window-housing can be made of a high density material (e.g. 12 g/cm.sup.3) with a high atomic number (e.g. 45), and can include an aperture with an increasing-inner-diameter region, with a smaller diameter closer to the electron-emitter and a larger diameter closer to the window-mount, for blocking x-rays and electrons. An example angle in the increasing-inner-diameter region is between 15 degrees and 35 degrees. The x-ray tube can further comprise a window-cap. The x-ray window can be sandwiched between the window-housing and the window-cap. The window-cap can be made of a high density material (e.g. 12 g/cm.sup.3) with a high atomic number (e.g. 45) for blocking x-rays in undesirable directions, and can include an aperture for allowing x-rays to transmit in desirable directions.

The improved cathode sub-assembly includes a solid cylindrical cathode of tungsten, a cylindrical holder concentric to the cathode with an internal radially directed rib receiving one end of the cathode, and a cylindrical reflector threadably mounted within the holder in circumferentially spaced relation to the cathode. The holder is threadably mounted in a support plate to be able to be readily removed for servicing and/or replacement.