In order to evaporate material, an electronic beam is guided over a melt surface in a periodic pattern by a detecting unit. Whether or not the actual pattern matches the target pattern specified by the deflecting unit is detected in principle on an image of the melt surface. In order to allow a better analysis of the image, the periodicity of the deflection pattern during the analysis of temporally successive images is taken into consideration.

In one embodiment, a multi charged-particle beam writing apparatus includes a plurality of blankers switching between ON and OFF state of a corresponding beam among multiple beams, a main deflector deflecting beams having been subjected to blanking deflection to a writing position of the beams in accordance with movement of a stage, a detector scanning a mark on the stage with each of the beams having been deflected by the main deflector and detecting a beam position from a change in intensity of reflected charged particles and a position of the stage, and a beam shape calculator switching an ON beam, scanning the mark with the ON beam, and calculating a shape of the multiple beams from a beam position. A shape of a deflection field of the main deflector is corrected by using a polynomial representing an amount of beam position shift that is dependent on a beam deflection position of the main deflector and then the mark is scanned with the ON beam. The polynomial is different for each ON beam.

An evaluation method according to an embodiment is to evaluate a precision of an aperture formed with multiple openings, and includes steps of forming a first evaluation pattern based on evaluation data using multiple electron beams generated by electron beam that has passed through the aperture, dividing the aperture into multiple regions, each of the regions including the multiple openings and defining the multiple divided regions, forming a second evaluation pattern based on evaluation data using the electron beam that has passed through a first divided region among the multiple divided regions, comparing the first evaluation pattern with the second evaluation pattern, and evaluating the precision of the aperture based on the comparison result between the first evaluation pattern and the second evaluation pattern.

A method is disclosed of removing a first material disposed over a second material adjacent to a field effect transistor gate having a gate sidewall layer that comprises an etch-resistant material on a gate sidewall. The method includes subjecting the first material to a gas cluster ion beam etch process to remove first material adjacent to the gate, and detecting exposure of the second material during the gas cluster ion beam (GCIB) etch process.

The present invention is directed to a technique for correcting processing positional deviation and processing size deviation during processing by a focused ion beam device. A focused ion beam device control method includes forming a first processed figure on the surface of a specimen through the application of a focused ion beam in a first processing range of vision; determining the position of a next, second processing range of vision based on the outer dimension of the first processed figure; and moving a stage to the position of the second processing range of vision thus determined. Further, the control method includes forming a second processed figure through the application of the focused ion beam in a second processing range of vision.

In one embodiment, a BAA apparatus 204 includes apertures 3, each of which being provided to blank charged particle beams 20. The apparatus 204 further includes first electrodes 6a, second electrodes 6b, first via plugs 5a, second via plugs 5c, drivers 2 and comparison circuitries 7 that are provided for each aperture 3, wherein a first electrode 6a and a second electrode 6b are opposite to each other, first and second via plug 5a and 5c are electrically connected to the first electrode 6a, a driver 2 supplies a driving signal to the first electrode 6a via the first via plug 5a, and a comparison circuitry 7 is provided to correspond to the first electrode 6a and compares the driving signal and a signal obtained from the second via 5c plug to output a comparison result signal indicating a result of the comparison.

A charged-particle beam exposure method includes providing a sample that has patterns having shot densities different from each other, using the sample to obtain pattern drift values correlated with the shot densities, and irradiating the sample with a charged-particle beam to perform an exposure process on the sample. The irradiating of the sample with the charged-particle beam is carried out while a deflection voltage, which is applied to the charged-particle beam to deflect the charged-particle beam, is corrected based on the pattern drift value corresponding to a shot density of a pattern to be formed on the sample.

Provided is a method of adjusting an electron-beam irradiated area in an electron beam irradiation apparatus that deflects an electron beam with a deflector to irradiate an object with the electron beam, the method including: emitting an electron beam while changing an irradiation position on an adjustment plate by controlling the deflector in accordance with an electron beam irradiation recipe, the adjustment plate detecting a current corresponding to the emitted electron beam; acquiring a current value detected from the adjustment plate; forming image data corresponding to the acquired current value; determining whether the electron-beam irradiated area is appropriate based on the formed image data; and updating the electron beam irradiation recipe when the electron-beam irradiated area is determined not to be appropriate.

In one embodiment, a charged particle beam writing method includes writing a first pattern statically in central part of a first substrate having Charge Dissipation Layer (CDL), calculating, based on a position of the written first pattern, a first correction coefficient, writing a second pattern statically applying with the first correction coefficient in central part of a second substrate having no CDL, calculating, based on a position of the written second pattern, a second correction coefficient, writing a third pattern continuously applying with the first correction coefficient in central part of a third substrate having CDL, calculating, based on a position of the written third pattern, a third correction coefficient, writing a fourth pattern statically applying with the first correction coefficient in wide range of a fourth substrate having CDL, and calculating, based on a position of the written fourth pattern, a fourth correction coefficient.

In a charged-particle multi-beam writing method a desired pattern is written on a target using a beam of energetic electrically charged particles, by imaging apertures of a pattern definition device onto the target, as a pattern image which is moved over the target. Thus, exposure stripes are formed which cover the region to be exposed in sequential exposures, and the exposure stripes are mutually overlapping, such that each area of said region is exposed by at least two different areas of the pattern image at different transversal offsets (Y1). For each pixel, a corrected dose amount is calculated by dividing the value of the nominal dose amount by a correction factor (q), wherein the same correction factor (q) is used with pixels located at positions which differ only by said transversal offsets (Y1) of overlapping stripes.