A method, an apparatus, and a program for more appropriately determining a condition for appropriately recognizing a semiconductor pattern are provided. A method for determining a condition related to a captured image of a charged particle beam apparatus including: acquiring, by a processor, a plurality of captured images, each of the captured images being an image generated by irradiating a pattern formed on a wafer with a charged particle beam, and detecting electrons emitted from the pattern, each of the captured images being an image captured according to one or more imaging conditions, the method further including: acquiring teaching information for each of the captured images; acquiring, by the processor, one or more feature determination conditions; calculating, by the processor, a feature for each of the captured images based on each of the feature determination conditions, at least one of the imaging condition and the feature determination condition being plural.

A system and a method for manipulating a beam of an Advanced Charge Controller module in different planes in an e-beam system are provided. Some embodiments of the system include a lens system configured to manipulate a beam in the tangential plane and the sagittal plane such that the beam spot is projected onto the wafer with high luminous energy. Some embodiments of the system include a lens system comprising at least two cylindrical lens.

Apparatuses, systems, and methods for beam array geometry optimization of a multi-beam inspection tool are disclosed. In some embodiments, a microelectromechanical system (MEMS) may include a first row of apertures; a second row of apertures positioned below the first row of apertures; a third row of apertures positioned below the second row of apertures; and a fourth row of apertures positioned below the third row of apertures; wherein the first, second, third, and fourth rows are parallel to each other in a first direction; the first and third rows are offset from the second and fourth rows in a second direction that is perpendicular to the first direction; the first and third rows have a first length; the second and fourth rows have a second length; and the first length is longer than the second length in the second direction.

A pattern inspection apparatus includes a secondary electron image acquisition mechanism to include a deflector deflecting multiple primary electron beams and a detector detecting multiple secondary electron beams, and acquire a secondary electron image corresponding to each of the multiple primary electron beams by scanning a target object with a pattern thereon with the multiple primary electron beams by the deflector, and detecting the multiple secondary electron beams from the target object by the detector, a storage device to store individual correction kernels each generated for individually adjusting a secondary electron image corresponding to each primary electron beam concerning a reference pattern to be commensurate with a reference blurred image, and a correction circuit to correct, by correspondingly using the individual correction kernel, the secondary electron image corresponding to each primary electron beam acquired from the inspection target object.

A multi-electron beam inspection apparatus includes first sample hold circuits, each configured to include a capacitor and a switch arranged for each of electrodes of each of a plurality of multipoles, and to hold, using the capacitor and the switch, a potential to be applied to the each of the electrodes, power sources configured to apply potentials to the plurality of first sample hold circuits, a control circuit configured to control the plurality of first sample hold circuits such that the plurality of potentials having been applied to the plurality of first sample hold circuits are held, in synchronization with swinging back of the collective beam deflection by the objective deflector, by a plurality of second sample hold circuits selected from the plurality of first sample hold circuits, and a detector configured to detect multiple secondary electron beams emitted because the substrate is irradiated with the multiple primary electron beams.

A multi-electron beam image acquisition apparatus includes a multiple-beam forming mechanism to form multiple primary electron beams, a primary-electron optical system to irradiate 1a sample with the multiple primary electron beams, a beam separator, arranged at a position conjugate to an image plane of each of the multiple primary electron beams, to form an electric field and a magnetic field to be mutually perpendicular, to separate multiple secondary electron beams, emitted from the sample due to irradiation with the multiple primary electron beams, from the multiple primary electron beams by using actions of the electric field and the magnetic field, and to have a lens action on the multiple secondary electron beams in at least one of the electric field and the magnetic field, a multi-detector to detect the multiple secondary electron beams, and a secondary-electron optical system to lead the multiple secondary electron beams to the multi-detector.

A method for particle beam-induced processing of a defect of a microlithographic photomask, including the steps of: a1) providing an image of at least a portion of the photomask, b1) determining a geometric shape of a defect in the image as a repair shape, c1) subdividing the repair shape into a number of n pixels in accordance with a first rasterization, d1) subdividing the repair shape into a number of m pixels in accordance with a second rasterization, the second rasterization emerging from a subpixel displacement of the first rasterization, e1) providing an activating particle beam and a process gas at each of the n pixels of the repair shape in accordance with the first rasterization, and f1) providing the activating particle beam and the process gas at each of the m pixels of the repair shape in accordance with the second rasterization.

A charged-particle tool including: a condenser lens array configured to separate a beam of charged particles into a first plurality of sub-beams along a respective beam path and to focus each of the sub-beams to a respective intermediate focus; an array of objective lenses, each objective lens configured to project one of the plurality of sub-beams onto a sample; a corrector including an array of elongate electrodes, the elongate electrodes extending substantially perpendicular to the beam paths of the first plurality of sub-beams and arranged such that a second plurality of the sub-beams propagate between a pair of the elongate electrodes, the second plurality of sub-beams being a subset of the first plurality of sub-beams; and an electric power supply configured to apply a potential difference between the pair of elongate electrodes so as to deflect the second plurality of sub-beams by a desired amount.

Aspects of the disclosure provide a method of tilting characterization. The method includes measuring a first tilting shift of structures based on a first disposition of the structures. The structures are formed in a vertical direction on a horizontal plane of a product. A second tilting shift of the structures is measured based on a second disposition of the structures. The second disposition is a horizontal flip of the first disposition. A corrected tilting shift is determined based on the first tilting shift and the second tilting shift.

A scanning electron microscope (SEM) device includes: an electron beam source configured to emit an electron beam; a lens unit disposed between the electron beam source and a stage configured to seat an object including structures having a pattern is seated, and including a scanning coil, the scanning coil configured to generate an electromagnetic field to provide a lens, and an astigmatism adjuster; and a control unit. The control unit is configured to change a working distance between the lens unit and the object to obtain a plurality of original images, obtain a pattern image, in which the structures appear, and a plurality of kernel images, in which a distribution of the electron beam on the object appears, from the plurality of original images, and control the astigmatism adjuster to adjust the focus and the astigmatism of the lens unit using feature values extracted from the plurality of kernel images.