Abstract: 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.

Abstract: 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.

Abstract: In one embodiment, a charged particle beam drawing method includes calculating a resist film reduction amount caused by etching from data representing a relation between a resist area rate and a resist film reduction amount and from an area rate of a pattern to be drawn, calculating a remaining resist-film thickness distribution by employing both an initial thickness of the resist film and the resist film reduction amount, estimating a dimension distribution of the light-shielding film pattern from the remaining resist-film thickness distribution, creating a first dimension correction map by determining a dimension correction amount from the estimated dimension distribution, creating a third dimension correction map by synthesizing a second dimension correction map to correct a relatively macroscopic dimensional variation and the first dimension correction map, and calculating an irradiation dose of the charged particle beam by employing the third dimension correction map.

Abstract: In one embodiment, a charged particle beam drawing method includes calculating a resist film reduction amount caused by etching from data representing a relation between a resist area rate and a resist film reduction amount and from an area rate of a pattern to be drawn, calculating a remaining resist-film thickness distribution by employing both an initial thickness of the resist film and the resist film reduction amount, estimating a dimension distribution of the light-shielding film pattern from the remaining resist-film thickness distribution, creating a first dimension correction map by determining a dimension correction amount from the estimated dimension distribution, creating a third dimension correction map by synthesizing a second dimension correction map to correct a relatively macroscopic dimensional variation and the first dimension correction map, and calculating an irradiation dose of the charged particle beam by employing the third dimension correction map.

Abstract: In one embodiment, A charged particle beam drawing apparatus includes an irradiation amount resetting processing circuitry changing the irradiation amount in the shot data to the irradiation amount lower limit value when the irradiation amount defined in the shot data is less than the irradiation amount lower limit value, a shot size adjustment processing circuitry changing the shot size defined in the shot data, based on an amount of the change in the irradiation amount, a shot position adjustment processing circuitry changing the shot position defined in the shot data, based on an amount of the change in the shot size, and a drawing device drawing a pattern by irradiating the substrate with the charged particle beam, using the shot data in which the irradiation amount, the shot size, and the shot position have been changed.

Abstract: In one embodiment, A charged particle beam drawing apparatus includes an irradiation amount resetting processing circuitry changing the irradiation amount in the shot data to the irradiation amount lower limit value when the irradiation amount defined in the shot data is less than the irradiation amount lower limit value, a shot size adjustment processing circuitry changing the shot size defined in the shot data, based on an amount of the change in the irradiation amount, a shot position adjustment processing circuitry changing the shot position defined in the shot data, based on an amount of the change in the shot size, and a drawing device drawing a pattern by irradiating the substrate with the charged particle beam, using the shot data in which the irradiation amount, the shot size, and the shot position have been changed.

Abstract: In a charged particle beam writing apparatus, a charged particle optical system includes a first, second, and third deflection control system configured to form a shot of a charged particle beam, control a shape and size of the shot, and control an irradiation position of the shot respectively. A shot data generation processing device generates shot data of writing a latent image on a resist layer in a sample, using (1) design data of a pattern to be formed in a member, wherein the member is formed in a sample, and the resist layer is formed on the member, and (2) correction information of a shot size and an irradiation shot position obtained from in-plane distribution data of an XY dimension variation amount of dimension measurement patterns. The dimension measurement patterns are formed by writing test patterns on a resist layer and transferring the test patterns onto a member.

Abstract: In a charged particle beam writing apparatus, a charged particle optical system includes a first, second, and third deflection control system configured to form a shot of a charged particle beam, control a shape and size of the shot, and control an irradiation position of the shot respectively. A shot data generation processing device generates shot data of writing a latent image on a resist layer in a sample, using (1) design data of a pattern to be formed in a member, wherein the member is formed in a sample, and the resist layer is formed on the member, and (2) correction information of a shot size and an irradiation shot position obtained from in-plane distribution data of an XY dimension variation amount of dimension measurement patterns. The dimension measurement patterns are formed by writing test patterns on a resist layer and transferring the test patterns onto a member.

Abstract: A charged particle beam writing apparatus includes an emission unit to emit a charged particle beam, a stage to mount thereon a target object to be written, an objective lens to focus the charged particle beam on a surface of the target object, a chamber to house the stage, a measurement unit to measure a partial pressure of a predetermined gas in the chamber in a state where a pressure inside the chamber is controlled to be lower than an atmospheric pressure, and an adjustment unit to adjust a focus position for focusing the charged particle beam on the target object, based on the partial pressure of the predetermined gas.

Abstract: A charged particle beam writing method includes determining whether a difference between one of the total area of a pattern and the number of shots in a stripe region with respect to one of adjacent stripe regions of the stripe regions and one of the total area and the number of shots with respect to the other of the adjacent stripe regions exceeds a threshold value, re-dividing, when the difference exceeds the threshold value, a stripe region where the total area or the number of shots is larger than that of the other stripe region in the adjacent stripe regions so that the difference of the total area or the number of shots becomes lower than or equal to the threshold value, and writing a pattern in the stripe regions including a re-divided stripe region, in the writing order of arrangement of the stripe regions.

Abstract: A charged particle beam writing apparatus includes an emission unit to emit a charged particle beam, a stage to mount thereon a target object to be written, an objective lens to focus the charged particle beam on a surface of the target object, a chamber to house the stage, a measurement unit to measure a partial pressure of a predetermined gas in the chamber in a state where a pressure inside the chamber is controlled to be lower than an atmospheric pressure, and an adjustment unit to adjust a focus position for focusing the charged particle beam on the target object, based on the partial pressure of the predetermined gas.

Abstract: A charged particle beam writing method includes determining whether a difference between one of the total area of a pattern and the number of shots in a stripe region with respect to one of adjacent stripe regions of the stripe regions and one of the total area and the number of shots with respect to the other of the adjacent stripe regions exceeds a threshold value, re-dividing, when the difference exceeds the threshold value, a stripe region where the total area or the number of shots is larger than that of the other stripe region in the adjacent stripe regions so that the difference of the total area or the number of shots becomes lower than or equal to the threshold value, and writing a pattern in the stripe regions including a re-divided stripe region, in the writing order of arrangement of the stripe regions.

Abstract: A writing method includes calculating a proximity effect-corrected dose for correcting a proximity effect in charged particle beam writing, for each first mesh region made by virtually dividing a writing region of a target object into a plurality of first mesh regions of a first mesh size, calculating a fogging effect-corrected dose by using the proximity effect-corrected dose calculated and an area density in the first mesh size with respect to a part of a calculation region for calculating the fogging effect-corrected dose for correcting a fogging effect in the charged particle beam writing, and by using an area density in a second mesh size larger than the first mesh size with respect to a remaining part of the calculation region, synthesizing the fogging effect-corrected dose and the proximity effect-corrected dose for the each first mesh region, and writing a pattern on the target object by using a charged particle beam based on a synthesized correction dose.

Abstract: A charged particle beam writing method on a chemical amplification type resist, comprising: coating said chemical amplification type resist which contains an acid diffusion inhibitor, on a surface of a mask substrate, exposing charged particle beams to said chemical amplification type resist layer on said surface of the mask substrate, baking said chemical amplification type resist layer which said charged particle beams were exposed, and developing said chemical amplification type resist after the baking, wherein an exposure current density of said electron beams exposing ranges of 50˜5000 A/cm2, said photo acid generator is in an amount ranging from 0.

Abstract: A writing method includes calculating a proximity effect-corrected dose for correcting a proximity effect in charged particle beam writing, for each first mesh region made by virtually dividing a writing region of a target object into a plurality of first mesh regions of a first mesh size, calculating a fogging effect-corrected dose by using the proximity effect-corrected dose calculated and an area density in the first mesh size with respect to a part of a calculation region for calculating the fogging effect-corrected dose for correcting a fogging effect in the charged particle beam writing, and by using an area density in a second mesh size larger than the first mesh size with respect to a remaining part of the calculation region, synthesizing the fogging effect-corrected dose and the proximity effect-corrected dose for the each first mesh region, and writing a pattern on the target object by using a charged particle beam based on a synthesized correction dose.

Abstract: The present invention realized the excellent dimensional accuracy of resist patterns by using a chemical amplification type resist whose effective acid diffusion length is shorten without decreasing throughput of a charged particle beam writing system. The resist pattern forming method of the present invention features that the amount of the acid diffusion inhibitor in a chemical amplification type resist in order to shorten the effective acid diffusion length increases and the current density of a charged particle exposure in order to prevent the throughput drop of the writing system increases.