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.

An emitter is configured to emit charged particles. The emitter comprises a body, a metal layer and a charged particle source layer. The body has a point. The metal layer is of a first metal on at least the point. The charged particle source layer is on the metal layer. The point comprises a second metal other than the first metal.

Systems, devices, and methods for performing a non-contact electrical measurement (NCEM) on a NCEM-enabled cell included in a NCEM-enabled cell vehicle may be configured to perform NCEMs while the NCEM-enabled cell vehicle is moving. The movement may be due to vibrations in the system and/or movement of a movable stage on which the NCEM-enabled cell vehicle is positioned. Position information for an electron beam column producing the electron beam performing the NCEMs and/or for the moving stage may be used to align the electron beam with targets on the NCEM-enabled cell vehicle while it is moving.

A multi-charged particle beam writing apparatus includes a movable stage to mount a substrate thereon, a shot data generation circuit to generate shot data of each shot of multiple charged particle beams, a shift amount calculation circuit to calculate a shift amount for collectively correcting positions of all of the multiple charged particle beams of the k-th shot, based on parameters related to at least the (k+1)th and subsequent shots (k being a natural number) of the multiple charged particle beams, and a writing mechanism including a deflector for deflecting the multiple charged particle beams, and to perform the k-th shot onto the substrate with the multiple charged particle beams while shifting the all of the multiple charged particle beams of the k-th shot by collective deflection according to the shift amount.

Systems and methods are described herein for electron-beam lithography. In some aspects, a photo electron emitter and channel array assembly (PEECAA) may include a photo-electron emitting cathode having a uniform planar surface and an array of beam channels proximate to the cathode. In some cases, at least one of the cathode or the array of beam channels is removable from the PEECAA. The array of beam channels may include a grid of apertures, a plurality of beam channels, and a shared lens array including a plurality of lenses proximate to an exit of the plurality of beam channels. Individual apertures of the grid of apertures align with individual beam channels to allow electrons from the cathode to pass through the array of beam channels and the shared lens array to form a pixelated pattern, such that, upon exposure to the target, the pixelated pattern is permanently formed on the target.

In a charged-particle lithography apparatus, during writing a desired pattern, the duration of exposure slots is adapted to compensate for fluctuations of the particle beam. In the writing process the aperture images are mutually overlapping on the target so each pixel is exposed through a number of aperture images overlapping at the respective pixel, which results in an exposure of the respective pixel through an effective pixel exposure time, i.e., the sum of durations of contributing exposure slots, and the exposure slot durations are adjusted by: (i) determining a desired duration of the effective pixel exposure time for the pixels, as a function of the time of exposure of the pixels, (ii) determining contributing exposure slots for the pixels, (iii) calculating durations for the contributing exposure slots thus determined such that the sum of the durations over said contributing exposure slots is an actual effective exposure time which approximates said desired duration of the effective pixel exposure time. The durations in step (iii) are calculated in accordance with a predetermined set of allowed durations, wherein at least one of the durations thus calculated is different from the other durations selected for said set of exposure slots.

A multi-charged particle beam writing apparatus includes a movable stage to mount a substrate thereon, a shot data generation circuit to generate shot data of each shot of multiple charged particle beams, a shift amount calculation circuit to calculate a shift amount for collectively correcting positions of all of the multiple charged particle beams of the k-th shot, based on parameters related to at least the (k+1)th and subsequent shots (k being a natural number) of the multiple charged particle beams, and a writing mechanism including a deflector for deflecting the multiple charged particle beams, and to perform the k-th shot onto the substrate with the multiple charged particle beams while shifting the all of the multiple charged particle beams of the k-th shot by collective deflection according to the shift amount.

Provided is a focused ion beam processing apparatus including: an ion source; a sample stage a condenser lens; an aperture having a slit in a straight line shape; a projection lens and the sample stage, wherein, in a transfer mode, by Köhler illumination, with an applied voltage of the condenser lens when a focused ion beam is focused on a main surface of the projection lens scaled to be 100, the applied voltage is set to be less than 100 and greater than or equal to 80; a position of the aperture is set such that the focused ion beam is masked by the aperture with the one side of the aperture at a distance greater than 0 μm and equal to or less than 500 μm from a center of the focused ion beam; and the shape of the slit is transferred onto the sample.

The present invention discloses an ion beam lithography method based on an ion beam lithography system. The ion beam lithography system includes a roll-roll printer placed in a vacuum, and a medium-high-energy wide-range ion source, a medium-low-energy wide-range ion source and a low-energy ion source installed on the roll-roll printer. The ion beam lithography method includes: first coating a polyimide (PI) substrate with a dry film, etching the dry film according to a preset circuit pattern, then using the ion beam lithography system to deposit a wide-energy-range metal ion on the circuit pattern to form a film substrate, and finally stripping the dry film off the film substrate to obtain a printed circuit board (PCB).

An e-beam apparatus is disclosed, the tool comprising an electron optics system configured to project an e-beam onto an object, an object table to hold the object, and a positioning device configured to move the object table relative to the electron optics system. The positioning device comprises a short stroke stage configured to move the object table relative to the electron optics system and a long stroke stage configured to move the short stroke stage relative to the electron optics system. The e-beam apparatus further comprises a magnetic shield to shield the electron optics system from a magnetic disturbance generated by the positioning device. The magnetic shield may be arranged between the positioning device and the electron optics system.