In order to compensate for undesired effects of varying elevation of a target with respect to a nominal target plane, during writing a desired pattern on the target in a charged-particle beam apparatus, the pattern is re-calculated in each of a number of segments of the target plane by: determining an elevation of the target in the segment from the nominal target plane; determining a local blur value which represents the actual value of blur corresponding to the elevation, with regard to a dependence of the blur upon the elevation of the target; calculating a convolution kernel which represents a point spreading function realizing a local blur value; and re-calculating a nominal exposure pattern by applying the kernel to the pattern. The convolution kernel corresponds to introducing an additional blur into the pattern in the segment, increasing the blur to a given target blur value which is uniform to all segments.

In one embodiment, a multi charged particle beam writing apparatus includes a measurement unit measuring a first beam shape of a multi-beam based on a beam current of each beam of the multi-beam or an intensity of charged particles reflected from a reflection mark provided on a stage, an amounts of adjustment calculator calculating amounts of adjustment of a reduction ratio and a rotation angle of the multi-beam based on the first beam shape, a correction map generation unit generating a first correction map in which an amount of displacement is defined that is obtained for each beam of the multi-beam based on a difference between a beam shape based on the amounts of adjustment and the first beam shape, a writing data processor generating shot data in which an amount of irradiation with each beam of the multi-beam is defined by converting writing data in which information regarding a graphic pattern to be written is defined, and correcting the amount of irradiation with each beam defined in the shot data based on the first correction map, and a controller controlling the reduction ratio and rotation angle of the multi-beam based on the amounts of adjustment.

Methods and apparatuses for providing an anisotropic ion beam for etching and treatment of substrate are discussed. In one embodiment, a system for processing a substrate includes a chamber, a chuck assembly, an ion source, and a grid system. The ion source includes grid system interfaces both the chamber and the ion source and includes a plurality of holes through which ions are extracted from the ion source to form an ion beam. The grid system is oriented so the ion beam is directed into the chamber toward the substrate support, and the array of holes of the grid system is defined vertically by a y-axis and horizontally by an x-axis, The array of holes is defined by hole densities that vary vertically in the y-axis such that the ion beam is caused to have an energy density gradient that is defined vertically in the y-axis.

A charged particle beam optical apparatus has a plurality of irradiation optical systems each of which irradiates an object with a charged particle beam and a first control apparatus configured to control a second irradiation optical system on the basis of an operation state of a first irradiation optical system.

In one embodiment, a charged particle beam writing apparatus includes an emitter emitting a charged particle beam, a first aperture shaping the charged particle beam, a second aperture shaping the charged particle beam transmitted through the first aperture, a projection lens projecting the charged particle beam transmitted through the first aperture on the second aperture, an object lens focusing the charged particle beam transmitted through the second aperture, the object lens being a magnetic field-type lens, and an electrostatic lens performing focus correction of the charged particle beam in accordance with a surface height of a substrate that is a writing target. The electrostatic lens is disposed inside the object lens, a positive voltage is applied to an electrode of the electrostatic lens. A strength of a magnetic field of the object lens at an upper end of the electrode has a predetermined value or less.

A multiple electron beam irradiation apparatus includes a first region setting circuit which sets a first frame region of a plurality of first frame regions which can be irradiated with remaining beams after excluding beams in one row and one column at end; a second region setting circuit which sets a second frame region of a plurality of second frame regions each having four corners equivalent to an irradiation position of the defective beam by using normal beams; and an electron beam irradiation mechanism which performs the first multiple electron beam irradiation processing for the each of the plurality of first frame regions of the target object by using the normal beams, and perform second multiple electron beam irradiation processing for each of the plurality of second frame regions by using at least beams at the four corners.

An ion implanter includes a beam generator that generates anion beam, a beam scanner that performs reciprocating scan with the ion beam in a first direction, a platen driving device that performs reciprocating motion of a wafer in a second direction perpendicular to the first direction, while holding the wafer so that a wafer processing surface is irradiated with the ion beam subject to the reciprocating scan, and a control device that changes a beam scan speed in the first direction and a wafer motion speed in the second direction in accordance with a beam irradiation position in the first direction and the second direction at which the wafer processing surface is irradiated with the ion beam so that ions having a desired two-dimensional non-uniform dose distribution are implanted into the wafer processing surface.

In one embodiment, a multi-beam writing method includes acquiring a plurality of pieces of position deviation data corresponding to a plurality of parameter values of a parameter that change position deviation amount of each beam of multi-beam irradiated on a substrate, calculating a plurality of pieces of reference coefficient data corresponding to each of the plurality of pieces of position deviation data, calculating coefficient data corresponding to a parameter value at an irradiation position of the multi-beam on the substrate using the plurality of pieces of reference coefficient data corresponding to the plurality of parameter values, modulating an irradiation amount of each beam of the multi-beam for each shot using the coefficient data, and writing a pattern by irradiating the substrate with each beam of at least a part of the multi-beam having the modulated irradiation amounts.

In one embodiment, a multi-beam writing method is for irradiating each of pixels defined on a substrate, placed on a stage, with each beam of a multi-beam to form a pattern. The method includes obtaining a position correction amount of the pattern by each of a plurality of sub-arrays into which an array of the multi-beam is divided at least in a predetermined direction, based on the positional deviation amount of each beam of each of the sub-arrays, which obtained by dividing an array of the multi-beam at least in the predetermined direction, calculating an dose of the each beam irradiated to each pixel for shifting the position of the pattern drawn for each of the sub-arrays based on the position correction, and performing multi-writing using at least a portion of each two or more of the sub-arrays with the calculated dose.

According to an embodiment, a charged particle beam apparatus includes a stage; a chamber; an emission source of the charged particle beam; an electronic optical system configured to emit the charged particle beam; an optical column including the emission source and the electronic optical system; a charged particle detector configured to detect a position of the charged particle beam; a first actuator configured to provide a frequency vibration to the stage based on a first excitation signal; a second actuator configured to provide a frequency vibration to the optical column based on a second excitation signal; a third actuator configured to provide a frequency vibration to the chamber based on a third excitation signal; and a controller configured to generate the first to third excitation signals.