In one embodiment, a charged particle beam writing apparatus includes a writer writing a pattern on a substrate placed on a stage by irradiating the substrate with a charged particle beam, a height detector detecting a surface height of a mark on the stage, an irradiation position detector detecting an irradiation position of the charged particle beam on the mark surface by irradiation with the charged particle beam focused at the surface height of the mark, a drift correction unit calculating an amount of drift of the charged particle beam on the mark surface from the irradiation position detected by the irradiation position detector, and generating correction information for correcting a shift in irradiation position caused by a drift on the substrate surface based on the amount of drift, and a writing control unit correcting the irradiation position of the charged particle beam by using the correction information.

A method for measuring conductance of a material real-time during etching/milling includes providing a fixture having a socket for receiving the material. The socket is attached to a printed circuit board (PCB) mounted on one side of a plate that has at least one opening for providing ion beam access to the material sample. Conductive probes extend from the other side of the PCB to contact and span a target area of the material. A measurement circuit in electrical communication with the probes measures the voltage produced when a current is applied across the material sample to measure changes in electrical properties of the sample over time.

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.

In one embodiment, a multi charged particle beam writing apparatus includes a plurality of reflective marks disposed on a stage, an inspection aperture member configured to allow one beam to pass therethrough, a first detector detecting a beam current of a beam passed through the inspection aperture member, a second detector detecting charged particles reflected from the reflective marks, a first beam shape calculator generating a beam image based on the beam currents detected by the first detector and calculating a reference beam shape, and a second beam shape calculator calculating a beam shape based on changes in intensity of the reflected charged particles and a position of the stage. The reference beam shape is calculated before writing. During writing, the beam shape based on reflected charged particles is calculated, and variation of the beam shape is added to the reference beam shape.

A thin-sample-piece fabricating device is provided with a focused-ion-beam irradiation optical system, a stage, a stage driving mechanism, and a computer. The focused-ion-beam irradiation optical system performs irradiation with a focused ion beam (FIB). The stage holds a sample piece (Q). The stage driving mechanism drives the stage. The computer sets a thin-piece forming region serving as a treatment region, as well as a peripheral section surrounding the entire periphery of the thin-piece forming region, on the sample piece (Q). The computer causes irradiation with the focused ion beam (FIB) from a direction crossing the irradiated face of the sample piece (Q) so as to perform etching treatment such that the thickness of the thin-piece forming region becomes less than the thickness of the peripheral section.

A charged-particle beam writing apparatus includes a writing chamber to house a stage having a writing object placed thereon, a beam irradiator to irradiate a charged particle beam to the writing object placed on the stage, a stage driver to move the stage, a temperature distribution calculator to calculate temperature distribution of the writing object caused by a heat source in the writing chamber, based on movement history information of the stage, a deformed amount calculator to calculate a deformed amount of the writing object based on a constraint condition of the writing object placed on the stage and the calculated temperature distribution, and a position corrector to correct an irradiation position of the charged particle beam to the writing object based on the calculated deformed amount. The beam irradiator irradiates the charged particle beam based on the irradiation position corrected by the position corrector.

In one embodiment, a charged particle beam writing apparatus includes a deflector deflecting a charged particle beam, a first correcting lens and a second correcting lens correcting a focus position of the charged particle beam, a focus correction amount calculator calculating a first correction amount for the focus position according to a change in a height position of a sample surface, and calculating a second correction amount for the focus position according to a change in shot size of the charged particle beam, a first DAC (digital to analog converter) amplifier applying a voltage for a ground potential based on the first correction amount to the first correcting lens, and a second DAC amplifier applying a voltage for a ground potential based on the second correction amount to the second correcting lens, an output of the second DAC amplifier being smaller than an output of the first DAC amplifier.

This invention relates to a method and a device for processing a surface of a substrate by means of a particle beam. The method comprises the irradiation of the surface of the substrate, wherein, in a first area of the surface of the substrate, the surface of the substrate is processed with the particle beam, which strikes the surface of the substrate in an unpulsed manner; and wherein, in a second area of the surface of the substrate, the surface of the substrate is processed with the particle beam, which strikes the surface of the substrate in a pulsed manner.

In one embodiment, a charged particle beam writing apparatus includes a writer writing a pattern on a substrate on a stage with a charged particle beam, a mark substrate disposed on the stage and having a mark, an irradiation position detector detecting an irradiation position of the charged particle beam on a mark surface, a height detector detecting a surface height of the substrate and the mark substrate, a drift correction unit calculating an amount of drift correction, and a writing control unit correcting the irradiation position of the charged particle beam by using the amount of drift correction. The mark substrate has a pattern region with a plurality of marks and a non-pattern region with no pattern therein, and at least part of the non-pattern region is disposed between different portions of the pattern region. The height detector detects a height of a detection point in the non-pattern region.

A method of manufacturing a semiconductor device includes reducing a thickness of a semiconductor substrate and/or forming a doped region in the semiconductor substrate. The method further includes changing an ion acceleration energy of an ion beam while effecting a relative movement between the semiconductor substrate and the ion beam impinging on the semiconductor substrate.