Cabinet (10) for accommodating electronic equipment (46). The cabinet comprises a casing (12) with an access opening (24) at a access side (23), and a second side (17) opposite to the access side, an electronic equipment rack (40a), a first plenum space (35) between the access side and the rack, and a channel (36) in fluid communication with the second side and the first plenum space. The cabinet encloses a first cooling medium (27) that is in thermal communication with the electronic equipment. A cooling arrangement (29) is provided at the second side, which comprises a flow generator (30) for generating a flow (f) of the first cooling medium from the first plenum space across the electronic equipment toward the second side, and a heat exchanger (31) for extracting heat from the first cooling medium. The first cooling medium is subsequently recirculated through the channel to the first plenum space.

In one embodiment, a first storage storing writing data, a second storage storing correction data for correcting an error in a writing position due to factors including bending of the substrate, a cell data allocator virtually dividing a writing region of the substrate into blocks, and allocating a cell to the blocks in consideration of the correction data, a plurality of bitmap data generators virtually dividing the blocks into meshes, calculating an irradiation amount per mesh region, and generating bitmap data which assigns the irradiation amount to each mesh region, and a shot data generator generating shot data that defines an irradiation time for each beam. The cell data allocator virtually divides the writing region by division lines in a direction different from a writing forward direction to generate a plurality of division regions. The plurality of bitmap data generators generate pieces of bitmap data of the different division regions.

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.

A multiple charged particle beam writing apparatus includes a rotatable shaping aperture array substrate, including plural openings, to form/shape multiple beams by letting portions of a charged particle beam individually pass through the plural openings, a data rotation correction circuitry to read writing data from a storage device, and generate pattern data, in which the entire figure pattern has been reversely rotated against a rotational deviation direction of an aperture array image by a rotational deviation amount of the aperture array image, using information on the rotational deviation amount of the aperture array image of the multiple beams on the target object caused by a residual error of rotation adjustment of the shaping aperture array substrate, and a blanking aperture array mechanism, rotatable with the shaping aperture array substrate, to provide individual blanking control of the multiple beams, based on the pattern data of the figure pattern reversely rotated.

An exposure device is provided, including: a body tube depressurized to produce a vacuum state therein; a plurality of charged particle beam sources that are provided in the body tube, and emit a plurality of charged particle beams in a direction of extension of the body tube; a plurality of electromagnetic optical elements, each being corresponding to one of the plurality of charged particle beams in the body tube, and controls the one of the plurality of charged particle beams; first and second partition walls that are arranged separately from each other in the direction of extension in the body tube, and form non-vacuum spaces between at least parts of the first and second partition walls; and a depressurization pump that depressurizes a non-vacuum space that contacts the first partition wall and a non-vacuum space that contacts the second partition wall to an air pressure between zero and atmospheric pressure.

In one embodiment, a charged particle beam writing apparatus includes a storage storing coefficients of a calculation formula for calculating a correction amount of a beam emission position according to an atmospheric pressure, a correction amount calculator calculating a correction amount of the beam emission position from a measured value of an atmospheric pressure sensor and the calculation formula using the coefficients, a writer writing a pattern on a substrate using a charged particle beam with the beam emission position adjusted based on shot data and the correction amount, a correction residual calculator calculating a correction residual for the emission position of the charged particle beam using a result of detection by a detector, and an updater updating the coefficients, when there is correlation between change in the correction residual and change in the atmospheric pressure.

A charged particle beam writing apparatus includes an enlarged pattern forming circuitry to form an enlarged pattern by enlarging a figure pattern to be written, depending on a shift number which is defined by the number of writing positions shifted in the x or y direction in plural writing positions where multiple writing is performed while shifting the position, a reduced pattern forming circuitry to form a reduced pattern by reducing the figure pattern, depending on the shift number, and an irradiation coefficient calculation circuitry to calculate an irradiation coefficient for modulating a dose of a charged particle beam irradiating each of small regions, using the enlarged and reduced patterns.

A charged particle beam writing method includes acquiring the deviation amount of the deflection position per unit tracking deflection amount with respect to each tracking coefficient of a plurality of tracking coefficients having been set for adjusting the tracking amount to shift the deflection position of a charged particle beam on the writing target substrate in order to follow movement of the stage on which the writing target substrate is placed, extracting a tracking coefficient based on which the deviation amount of the deflection position per the unit tracking deflection amount is closest to zero among the plurality of tracking coefficients, and writing a pattern on the writing target substrate with the charged particle beam while performing tracking control in which the tracking amount has been adjusted using the tracking coefficient extracted.

A multiple charged particle beam writing apparatus includes a rotatable shaping aperture array substrate, including plural openings, to form/shape multiple beams by letting portions of a charged particle beam individually pass through the plural openings, a data rotation correction circuitry to read writing data from a storage device, and generate pattern data, in which the entire figure pattern has been reversely rotated against a rotational deviation direction of an aperture array image by a rotational deviation amount of the aperture array image, using information on the rotational deviation amount of the aperture array image of the multiple beams on the target object caused by a residual error of rotation adjustment of the shaping aperture array substrate, and a blanking aperture array mechanism, rotatable with the shaping aperture array substrate, to provide individual blanking control of the multiple beams, based on the pattern data of the figure pattern reversely rotated.

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.