Disclosed are an apparatus and method for generating a plurality of substantially collimated charged particle beamlets. The apparatus includes a charged particle source for generating a diverging charged particle beam, a beam splitter for splitting the charged particle beam in an array of charged particle beamlets, a deflector array includes an array of deflectors including one deflector for each charged particle beamlet of said array of charged particle beamlets, wherein the deflector array is configured for substantially collimating the array of diverging charged particle beamlets. The apparatus further includes a beam manipulation device configured for generating electric and/or magnetic fields at least in an area between the charged particle source and the deflector array. The apparatus has a central axis, and the beam manipulation device is configured for generating electric and/or magnetic fields substantially parallel to the central axis and substantially perpendicular to the central axis.

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 particle-optical arrangement comprises a charged-particle source for generating a beam of charged particles; a multi-aperture plate arranged in a beam path of the beam of charged particles, wherein the multi-aperture plate has a plurality of apertures formed therein in a predetermined first array pattern, wherein a plurality of charged-particle beamlets is formed from the beam of charged particles downstream of the multi-aperture plate, and wherein a plurality of beam spots is formed in an image plane of the apparatus by the plurality of beamlets, the plurality of beam spots being arranged in a second array pattern; and a particle-optical element for manipulating the beam of charged particles and/or the plurality of beamlets; wherein the first array pattern has a first pattern regularity in a first direction, and the second array pattern has a second pattern regularity in a second direction electron-optically corresponding to the first direction, and wherein the second regularity is higher than the first regularity.

In one embodiment, a multi charged particle beam writing apparatus includes an aperture plate having a plurality of holes to form multiple beams, a blanking aperture array having a plurality of blankers which switch ON-OFF of corresponding respective beams among the multiple beams, a stage on which a writing target substrate is placed, an inspection aperture provided on the stage and that allows one beam among the multiple beams to pass therethrough, a deflector deflecting the multiple beams, a current detector detecting a beam current of each of the multiple beams that has passed through the inspection aperture in a case where the multiple beams are scanned on the inspection aperture, and a control computing machine that generates a beam image based on the detected beam current and detects a defect of the blanking aperture array or the aperture plate based on the beam image.

According to one embodiment, a multi charged particle beam writing apparatus includes an objective lens adjusting a focus position of multiple beams, a coil correcting astigmatism of the multiple beams, an inspection aperture disposed in a stage and configured to allow one beam of the multiple beams to pass therethrough, a deflector deflecting the multiple beams, a current detector detecting a beam current of each beam of the multiple beams scanned over the inspection aperture in the XY direction and passed through the inspection aperture, and a controller generating a beam image on the basis of the detected beam current, calculating a feature quantity of the beam image, and controlling the objective lens or the coil on the basis of the feature quantity.

In one embodiment, a multi charged particle beam writing apparatus includes an aperture plate forming multiple beams, a stage on which a writing target substrate is placed, a stage position detector detecting the position of the stage, an inspection aperture plate provided in the stage, the inspection aperture plate permitting one of the multiple beams to pass through the inspection aperture plate, a deflector deflecting the multiple beams, a current detector detecting a beam current of each of the multiple beams scanned over the inspection aperture plate in X and Y directions and passed through the inspection aperture plate, and a control computer generating a beam image based on the detected beam currents and calculating positions of the beams based on the beam image and the position of the stage.

In one embodiment, a multi charged particle beam writing apparatus includes a blanking plate including a plurality of blankers, bitmap generation processing circuitry generating bitmap data for each writing pass of multi-pass writing, the bitmap data specifying irradiation time periods for a plurality of irradiation positions, a plurality of dose correction units configured to receive bitmap subdata items obtained by dividing the bitmap data from the bitmap generation processing circuitry, and correct the irradiation time periods to generate a plurality of dose data items corresponding to respective processing ranges, and data transfer processing circuitry transferring the plurality of dose data items to the blanking plate through a plurality of signal line groups. Each of the signal line groups corresponds to the blankers located in a predetermined region of the blanking plate. The data transfer processing circuitry changes the signal line groups, used to transfer the plurality of dose data items generated by the respective dose correction units, for each writing pass.

A sub-beam aperture array for forming a plurality of sub-beams from one or more charged particle beams. The sub-beam aperture array comprises one or more beam areas, each beam area comprising a plurality of sub-beam apertures arranged in a non-regular hexagonal pattern, the sub-beam apertures arranged so that, when projected in a first direction onto a line parallel to a second direction, the sub-beam apertures are uniformly spaced along the line, and wherein the first direction is different from the second direction. The system further comprises a beamlet aperture array with a plurality of beamlet apertures arranged in one or more groups. The beamlet aperture array is arranged to receive the sub-beams and form a plurality of beamlets at the locations of the beamlet apertures of the beamlet array.

The disclosure relates to a charged particle beam apparatus configured to project charged particle beams towards a sample. The charged particle beam apparatus comprises: a plurality of charged particle-optical columns configured to project respective charged particle beams towards the sample, wherein each charged particle-optical column comprises: a charged particle source configured to emit the charged particle beam towards the sample, the charged particle sources being comprised in a source array; an objective lens comprising an electrostatic electrode configured to direct the charged particle beam towards the sample; and a detector associated with the objective lens array, configured to detect signal charged particles emitted from the sample. The objective lens is the most down-beam element of the charged particle-optical column configured to affect the charged particle beam directed towards the sample.

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.