The purpose of the present invention is to provide a charged particle beam device with which it is possible to identify, to a high degree of accuracy, repeat patterns generated by a multiple exposure method such as SADP or SAQP. In order to achieve this purpose, there is proposed a charged particle beam device for: irradiating a first position on a sample with a charged particle beam to form an irradiation mark on the sample; after the formation of the irradiation mark, scanning the charged particle beam on a first visual field which includes the first position and which is larger than the irradiation mark, and thereby acquiring a first image; scanning the charged particle beam on a second visual field which includes the first position, which is larger than the irradiation mark, and which is in a different position from the first visual field, thereby acquiring a second image; and synthesizing the first image and the second image so as to overlap the irradiation marks included in the first image and the second image.

A multi-charged particle beam inspection apparatus includes a movable stage to place thereon an inspection substrate where plural dies each with the same pattern are arranged in a predetermined direction, a pitch acquisition circuit to acquire an arrangement pitch of plural dies, a magnification control circuit to control, when imaging the inspection substrate with multi-charged particle beams while continuously moving the stage, magnification of the multi-charged particle beams to be a controlled magnification such that the arrangement pitch of the plural dies becomes a natural number (2 or greater) multiple of an imaging region cycle in the predetermined direction of plural imaging regions to be individually imaged by each beam at each arrangement position of the multi-charged particle beams, and an acquisition mechanism to acquire inspection images of the plural dies on the inspection substrate, using the multi-charged particle beams whose magnification has been controlled to be the controlled magnification.

A method for process analysis includes acquiring first inspection data, using a first inspection modality, with respect to a substrate having multiple instances of a predefined pattern of features formed thereon using different, respective sets of process parameters. Characteristics of defects identified in the first inspection data are processed so as to select a first set of defect locations in which the first inspection data are indicative of an influence of the process parameters on the defects. Second inspection data are acquired, using a second inspection modality having a finer resolution than the first inspection modality, of the substrate at the locations in the first set. The defects appearing in the second inspection data are analyzed so as to select, from within the first set of the locations, a second set of the locations in which the second inspection data are indicative of an optimal range of the process parameters.

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.

An overlay metrology system includes a particle-beam metrology tool to scan a particle beam across an overlay target on a sample including a first-layer target element and a second-layer target element. The overlay metrology system may further include a controller to receive a scan signal from the particle-beam metrology tool, determine symmetry measurements for the scan signal with respect to symmetry metrics, and generate an overlay measurement between the first layer and the second layer based on the symmetry measurements in which an asymmetry of the scan signal is indicative of a misalignment of the second-layer target element with respect to the first-layer target element and a value of the overlay measurement is based on the symmetry measurements.

A charged particle beam writing apparatus includes a writing data generation circuitry to input character information or information of an item selected, for specifying an apparatus quality check pattern used for evaluating apparatus quality of a charged particle beam writing apparatus, and to generate writing data of the apparatus quality check pattern based on the character information or the information of the item selected, and a combination circuitry to input writing data of an actual chip pattern to be written on a target object, and to combine the writing data of the actual chip pattern and the writing data of the apparatus quality check pattern such that the actual chip pattern and the apparatus quality check pattern do not overlap with each other.

A multiple charged particle beam writing apparatus includes a defective pattern data generation circuitry configured to generate defective pattern data of a defective pattern having a shape of the defective region in the writing region; a reverse pattern data generation circuitry configured to generate reverse pattern data by reversing the defective pattern data; a combined-value pixel data generation circuitry configured to generate, for the each pixel, combined-value pixel data by adding a value defined in a reverse pattern pixel data and a value defined in a writing pattern pixel data; and a writing mechanism configured to perform multiple writing, using multiple charged particle beams, on the target object such that the each pixel is irradiated with a beam of a dose corresponding to a value defined in the combined-value pixel data.

An overlay metrology system includes a particle-beam metrology tool to scan a particle beam across an overlay target on a sample including a first-layer target element and a second-layer target element. The overlay metrology system may further include a controller to receive a scan signal from the particle-beam metrology tool, determine symmetry measurements for the scan signal with respect to symmetry metrics, and generate an overlay measurement between the first layer and the second layer based on the symmetry measurements in which an asymmetry of the scan signal is indicative of a misalignment of the second-layer target element with respect to the first-layer target element and a value of the overlay measurement is based on the symmetry measurements.

In one embodiment, a method of obtaining a beam deflection shape includes using a plurality of beams to write a line pattern on a substrate by deflecting the plurality of beams, the plurality of beams being beams in the i-th row (i is an integer satisfying 1im) among multiple charged-particle beams including beams of m rows and n columns (m and n are integers equal to or greater than two), the deflection being performed in such a manner that a writing area for a beam in the j-th column (j is an integer satisfying 1jn1) is continuously adjacent to a writing area for a beam in the (j+1)th column, measuring a degree of unevenness of an edge of the line pattern, and obtaining a deflection shape of the beam based on the degree of unevenness.

Provided is an assembly for inspecting the surface of a sample. The assembly includes two or more multi-beam electron column units. Each unit has: a single thermal field emitter for emitting a diverging electron beam towards a beam splitter; wherein the beam splitter includes a first multi-aperture plate having multiple apertures for creating multiple primary electron beams; a collimator lens for collimating the diverging electron beam from the emitter; an objective lens unit for focusing said multiple primary electron beams on said sample; and a multi-sensor detector system for separately detecting the intensity of secondary electron beams created by each one of said focused primary electron beams on said sample. The two or more multi-beam electron column units are arranged adjacent to each other for inspecting different parts of the surface of the sample at the same time.