A charged particle beam writing apparatus according to one aspect of the present invention includes an emission unit to emit a charged particle beam, an electron lens to converge the charged particle beam, a blanking deflector, arranged backward of the electron lens with respect to a direction of an optical axis, to deflect the charged particle beam in the case of performing a blanking control of switching between beam-on and beam-off, a blanking aperture member, arranged backward of the blanking deflector with respect to the direction of the optical axis, to block the charged particle beam having been deflected to be in a beam-off state, and a magnet coil, arranged in a center height position of the blanking deflector, to deflect the charged particle beam.

In one embodiment, a charged particle beam drawing apparatus includes a drawing unit that draws a pattern in a drawing area on a substrate and a control processing circuitry that controls the drawing unit via a process including receiving drawing data with a hierarchical correction map input to the control processing circuitry. The drawing data with the hierarchical map includes a plurality of files in which division maps are respectively described in files in units of subframes. Each division map includes dose correction information associated with corresponding one of blocks of the drawing area. The process further includes generating shot data by performing a data conversion process on the drawing data, reading a division map corresponding to a block in the area to be drawn from the hierarchical correction map, calculating a dose, and controlling the drawing unit based on the shot data and the calculated dose.

In one embodiment, a settling time determination method includes deflecting a charged particle beam by applying a voltage outputted from an amplifier to a first deflector while changing a deflection settling time, and writing an evaluation pattern, measuring a position of the evaluation pattern, and determining a position displacement amount of the measured position from a design position, performing fitting of the position displacement amount for the deflection settling time on a first output waveform of the amplifier, and determining a deflection settling time in which the position displacement amount is within a predetermined range.

In one embodiment, a charged particle beam writing method includes dividing a figure pattern defined in writing data into a plurality of shot figures, virtually dividing a writing target substrate into a plurality of mesh regions, and calculating a correction irradiation amount to correct proximity effect and middle range effect for each of the mesh regions based on a position of the figure pattern, calculating an irradiation amount for each of the plurality of shot figures using the correction irradiation amount, calculating an insufficient irradiation amount at an edge portion of the shot figure based on the irradiation amount, resizing the shot figure based on the insufficient irradiation amount, and writing the resized shot figure on the writing target substrate using a charged particle beam in the irradiation amount.

An electron beam writing apparatus comprising, a cathode configured to emit an electron beam, a condition controller configured to change a condition under which the electron beam is emitted from the cathode in a plurality of ways, and a prediction unit configured to predict a life span of the cathode based on a temporal change in an amount of fluctuation of a beam characteristic of the electron beam to a change in the condition when the condition is changed.

A drawing apparatus includes: a drawing part; a cleaning-gas generator; a first valve between the cleaning-gas generator and the drawing part and adjusting a supply amount of gas to the drawing part; a first pressure gauge measuring a pressure in the drawing part; a compensation-gas introducing part introducing compensation-gas to be supplied between the cleaning-gas generator and the first valve; a second valve between the compensation-gas introducing part and the first valve and adjusting a supply amount of the compensation-gas; and a valve controller controlling the first and second valves, wherein the valve controller controls the first valve to supply the cleaning-gas at a predetermined flow rate to the drawing part and controls the second valve to cause a pressure in the drawing part to be a predetermined pressure when the first pressure gauge detects a pressure reduction due to a reduction in a supply flow rate of the cleaning-gas.

A semiconductor device according to an embodiment includes: a substrate including a plurality of through holes provided at predetermined intervals along a first direction in a substrate surface and along a second direction intersecting the first direction in the substrate surface; an insulating layer provided on the substrate, the insulating layer being penetrated by the through holes; a plurality of first electrodes provided on the insulating layer, the first electrodes being adjacent to the respective through holes in the first direction; a plurality of second electrodes provided on the insulating layer, the second electrodes being adjacent to the respective through holes in the first direction, the second electrodes being provided to face the first electrodes, the second electrodes being held at a predetermined potential; and a wiring layer provided on the insulating layer, the wiring layer electrically connecting the adjacent second electrodes.

Methods for reticle enhancement technology (RET) for use with variable shaped beam (VSB) lithography include inputting a desired pattern to be formed on a substrate; determining an initial mask pattern from the desired pattern for the substrate; optimizing the initial mask pattern for wafer quality using a VSB exposure system; and outputting the optimized mask pattern. Methods for fracturing a pattern to be exposed on a surface using VSB lithography include inputting an initial pattern; overlaying the initial pattern with a two-dimensional grid, wherein an initial set of VSB shots are formed by the union of the initial pattern with locations on the grid; merging two or more adjacent shots in the initial set of VSB shots to create a larger shot in a modified set of VSB shots; and outputting the modified set of VSB shots.

Methods for reticle enhancement technology (RET) for use with variable shaped beam (VSB) lithography include determining an initial mask pattern from a desired pattern for a substrate; calculating a first substrate pattern from the initial mask pattern; determining an initial set of VSB shots that will form the initial mask pattern; calculating a simulated mask pattern from the initial set of VSB shots; calculating a second substrate pattern from the simulated mask pattern; and adjusting the initial set of VSB shots, wherein the adjusting of the initial set of VSB shots creates an adjusted set of VSB shots.

In a charged particle beam writing method according to an embodiment, a charged particle beam is deflected by a deflector, and a pattern is written by irradiating, with the charged particle beam, a substrate having a resist film formed thereon. The method includes irradiating a pattern region, in which a pattern is to be formed, with a beam at a first dose, irradiating at least part of a non-pattern region, in which a pattern is not to be formed, with the charged particle beam at a second dose, at which the resist film is not dissolved away, and determining the second dose based on the first dose and a charge amount of the resist film corresponding to a pattern density of the pattern region, wherein a charge amount difference between the pattern region and a non-dissolution irradiation region, which is irradiated at the second dose, is smaller than that obtained when the second dose is zero.