A pattern inspection apparatus according to an aspect described herein includes: a stage on which an object to be inspected is capable to be mounted, a multibeam column that irradiates the object to be inspected with multi-primary electron beams, and a multi-detector including a first detection pixel that receives irradiation of a first secondary electron beam emitted after a first beam scanning region of the object to be inspected is irradiated with a first primary electron beam of the multi-primary electron beams and a second detection pixel that receives irradiation of a second secondary electron beam emitted after a second beam scanning region adjacent to the first beam scanning region of the object to be inspected and overlapping with the first beam scanning region is irradiated with a second primary electron beam adjacent to the first primary electron beam of the multi-primary electron beams; a comparison unit that obtains a difference in beam intensity between the first primary electron beam and the second primary electron beam by comparing overlapping portions of a first frame image acquired through entering of the first secondary electron beam into the first detection pixel and a second frame image acquired through entering of the second secondary electron beam into the second detection pixel; and a sensitivity adjustor that adjusts detection sensitivity of the first detection pixel and/or the second detection pixel so as to correct the difference in beam intensity.

A pattern inspection apparatus according to an aspect described herein includes: a stage on which an object to be inspected is capable to be mounted, a multibeam column that irradiates the object to be inspected with multi-primary electron beams, and a multi-detector including a first detection pixel that receives irradiation of a first secondary electron beam emitted after a first beam scanning region of the object to be inspected is irradiated with a first primary electron beam of the multi-primary electron beams and a second detection pixel that receives irradiation of a second secondary electron beam emitted after a second beam scanning region adjacent to the first beam scanning region of the object to be inspected and overlapping with the first beam scanning region is irradiated with a second primary electron beam adjacent to the first primary electron beam of the multi-primary electron beams; a comparison unit that obtains a difference in beam intensity between the first primary electron beam and the second primary electron beam by comparing overlapping portions of a first frame image acquired through entering of the first secondary electron beam into the first detection pixel and a second frame image acquired through entering of the second secondary electron beam into the second detection pixel; and a sensitivity adjustor that adjusts detection sensitivity of the first detection pixel and/or the second detection pixel so as to correct the difference in beam intensity.

An emitter according to the present disclosure includes: first and second heaters generating heat by energization; an electron source comprising a first material emitting an electron by being heated by the first and second heaters; and an intermediate member interposed between the electron source, and the first and second heaters, the intermediate member comprising a second material lower in thermal conductivity than the first material.

A system and apparatus for electron beam melting comprises a superconducting radio frequency accelerator configured to produce an electron beam, a conduction cooling system configured to cool the superconducting radio frequency accelerator, and an electron beam melting system wherein the electron beam melts power in a build chamber of the electron beam melting apparatus.

An electromagnetic lens includes a coil, and a pole piece configured to include an upper wall, a lower wall, an outer peripheral wall and an inner peripheral wall which are formed using a conductive magnetic material, to surround the coil by the upper wall, the lower wall, the outer peripheral wall and the inner peripheral wall, one of opposite facing surfaces of an upper part and a lower part of the inner peripheral wall and opposite facing surfaces of the upper wall and the inner peripheral wall being insulated electrically, the outer peripheral wall including a laminated structure where a magnetic material and an insulator are alternately laminated in a direction of a central axis of a trajectory of a passing electron beam, and to be covered at least the laminated structure of the outer peripheral wall with an insulator.

An electromagnetic lens includes a coil, and a pole piece configured to include an upper wall, a lower wall, an outer peripheral wall and an inner peripheral wall which are formed using a conductive magnetic material, to surround the coil by the upper wall, the lower wall, the outer peripheral wall and the inner peripheral wall, one of opposite facing surfaces of an upper part and a lower part of the inner peripheral wall and opposite facing surfaces of the upper wall and the inner peripheral wall being insulated electrically, the outer peripheral wall including a laminated structure where a magnetic material and an insulator are alternately laminated in a direction of a central axis of a trajectory of a passing electron beam, and to be covered at least the laminated structure of the outer peripheral wall with an insulator.

An electron source has an insulating base, a pair of conductive terminals, an insulating support member, a drift isolation member, an emitter-cathode, and one or more heating elements. The conductive terminals are exposed from a first surface of the insulating base. The insulating support member extends from the first surface of the insulating base. The drift isolation member is disposed at an end of the insulating support member remote from the insulating base. The emitter-cathode is coupled to the drift isolation member. The one or more heating elements are coupled to the conductive terminals and the drift isolation member. The combination of the drift isolation member with the insulating support member can prevent stress-induced drift from impacting position of the emitter-cathode, thereby improving the mechanical stability of the electron source.

The disclosed embodiments relate to a charged particle source module for generating and emitting a charged particle beam, such as an electron beam, comprising: a frame including a first frame part, a second frame part, and one or more rigid support members which are arranged between said first frame part and said second frame part; a charged particle source arrangement for generating a charged particle beam, such as an electron beam, wherein said charged particle source arrangement, such as an electron source, is arranged at said second frame part; and a power connecting assembly arranged at said first frame part, wherein said charged particle source arrangement is electrically connected to said connecting assembly via electrical wiring.

A charged particle beam source, such as for use in an electron microscope, can include a mounting member defining a first opening at a free end of the mounting member and a bore extending from the first opening into the mounting member along a longitudinal axis of the mounting member. A second opening can be defined in a side wall of the mounting member and can extend between an outer surface of the mounting member and the bore, the second opening being spaced apart from the first opening along the longitudinal axis of the mounting member. An emitter member can be received in the bore and aligned along the longitudinal axis of the mounting member. A fixative material can be received in the bore and in the second opening to retain the emitter member in the bore.

In an electron source including a suppressor electrode having an opening at one end portion thereof in a direction along a central axis and an electron emission material having a distal end protruding from the opening, the suppressor electrode further includes a receding portion receding to a position farther from the distal end of the electron emission material than the opening in the direction along the central axis at a position in an outer peripheral direction than the opening, and at least a part of the receding portion is disposed within a diameter of 2810 μm from a center of the opening. Accordingly, an electron source, an electron gun, and a charged particle beam device such as an electron microscope using the same, in which a machine difference in a device performance due to an axial shift between the electron emission material and the suppressor electrode is reduced, are implemented.