An apparatus may include a first grounded drift tube, arranged to accept a continuous ion beam, at least two AC drift tubes, arranged in series, downstream to the first grounded drift tube, and a second grounded drift tube, downstream to the at least two AC drift tubes. The apparatus may include an AC voltage assembly, electrically coupled to at least two AC drift tubes. The AC voltage assembly may include a first AC voltage source, coupled to deliver a first AC voltage signal at a first frequency to a first AC drift tube of at least two AC drift tubes. The AC voltage assembly may further include a second AC voltage source, coupled to deliver a second AC voltage signal at a second frequency to a second AC drift tube of the at least two AC drift tubes, wherein the second frequency comprises an integral multiple of the first frequency.

A method for scanning a sample by a charged particle beam tool is provided. The method includes providing the sample having a scanning area including a plurality of unit areas, scanning a unit area of the plurality of unit areas, blanking a next unit area of the plurality of unit areas adjacent to the scanned unit area, and performing the scanning and the blanking the plurality of unit areas until all of the unit areas are scanned.

The invention relates to an exposure apparatus and a method for projecting a charged particle beam onto a target. The exposure apparatus comprises a charged particle optical arrangement comprising a charged particle source for generating a charged particle beam and a charged particle blocking element and/or a current limiting element for blocking at least a part of a charged particle beam from a charged particle source. The charged particle blocking element and the current limiting element comprise a substantially flat substrate provided with an absorbing layer comprising Boron, Carbon or Beryllium. The substrate further preferably comprises one or more apertures for transmitting charged particles. The absorbing layer is arranged spaced apart from the at least one aperture.

An apparatus may include a first grounded drift tube, arranged to accept a continuous ion beam, at least two AC drift tubes, arranged in series, downstream to the first grounded drift tube, and a second grounded drift tube, downstream to the at least two AC drift tubes. The apparatus may include an AC voltage assembly, electrically coupled to at least two AC drift tubes. The AC voltage assembly may include a first AC voltage source, coupled to deliver a first AC voltage signal at a first frequency to a first AC drift tube of at least two AC drift tubes. The AC voltage assembly may further include a second AC voltage source, coupled to deliver a second AC voltage signal at a second frequency to a second AC drift tube of the at least two AC drift tubes, wherein the second frequency comprises an integral multiple of the first frequency.

A measuring apparatus that irradiates a sample with a charged particle beam to observe the sample includes a particle source that outputs the charged particle beam, a lens that collects the charged particle beam, a detector that detects a signal of emitted electrons emitted from the sample which is irradiated with the charged particle beam, and a control device that controls the output of the charged particle beam and the detection of the signal of the emitted electrons in accordance with an observation condition, in which the control device sets, as the observation condition, a first parameter for controlling an irradiation cycle of the charged particle beam, a second parameter for controlling a pulse width of the pulsed charged particle beam, and a third parameter for controlling detection timing of the signal of the emitted electron within the irradiation time of the pulsed charged particle beam, and the third parameter is determined in accordance with a difference in intensity of signals of the plurality of the emitted electrons emitted from the irradiation position of the charged particle beam.

A multi-beam charged particle beam device is described. The multi-beam charged particle beam device includes a charged particle source configured to emit a primary charged particle beam; an aperture arrangement having openings configured to generate at least a first beamlet and a second beamlet of the primary charged particle beam; and a blanking device, the blanking device includes at least a first blanking deflector for the first beamlet and a second blanking deflector for the second beamlet; and a shield assembly having a first shielding element partially or fully surrounding the first blanking deflector.

An apparatus may include a first grounded drift tube, arranged to accept a continuous ion beam, at least two AC drift tubes, arranged in series, downstream to the first grounded drift tube, and a second grounded drift tube, downstream to the at least two AC drift tubes. The apparatus may include an AC voltage assembly, electrically coupled to at least two AC drift tubes. The AC voltage assembly may include a first AC voltage source, coupled to deliver a first AC voltage signal at a first frequency to a first AC drift tube of at least two AC drift tubes. The AC voltage assembly may further include a second AC voltage source, coupled to deliver a second AC voltage signal at a second frequency to a second AC drift tube of the at least two AC drift tubes, wherein the second frequency comprises an integral multiple of the first frequency.

A multi-beam charged particle beam device is described. The multi-beam charged particle beam device includes a charged particle source configured to emit a primary charged particle beam; an aperture arrangement having openings configured to generate at least a first beamlet and a second beamlet of the primary charged particle beam; and a blanking device, the blanking device includes at least a first blanking deflector for the first beamlet and a second blanking deflector for the second beamlet; and a shield assembly having a first shielding element partially or fully surrounding the first blanking deflector.

In one embodiment, a data processing method is for processing data in a writing apparatus performing multiple writing by using multiple beams. The data is for controlling an irradiation amount for each beam. The method includes generating irradiation amount data for each of a plurality of layers, the irradiation amount data defining an irradiation amount for each of a plurality of irradiation position, and the plurality of layers corresponding to writing paths in multiple writing, performing a correction process on the irradiation amounts defined in the irradiation amount data provided for each layer, calculating a sum of the irradiation amounts for the respective irradiation positions defined in the corrected irradiation amount data, comparing the sums between the plurality of layers, and determining whether or not an error has occurred in the correction process based on the comparison result.

A charged particle beam dump for a charged particle beam device is described. The beam dump includes an annular shaped body having an inner perimeter wall that defines an open annulus for passing of primary charged particle beamlets, the annular shaped body further having an outer perimeter wall and a bottom wall; and an annular shaped electrode provided partially above the annular shaped body having an inner perimeter side and an outer perimeter side, wherein the inner perimeter side is outside of the radius of the inner perimeter wall of the annular shaped body.