A charged particle beam drawing device includes: a storage unit that stores a pattern generation program for generating pattern data, the pattern generation program being a program in which an instruction for specifying a type of a figure and an instruction for specifying a regular arrangement of the figure are described; an execution unit that executes the pattern generation program stored in the storage unit; and a control unit that performs drawing control based on the pattern data generated by the executed pattern generation program.

There is provided a control device for controlling a charged particle beam apparatus, wherein the beam apparatus comprises a workpiece stage having at least two turning axes which are not parallel to each other and an irradiation unit, and the control device comprises an angle calculation unit that based on a direction of a first processing in which a processed surface having a normal line not parallel to any of the turning axes is generated in the workpiece by the irradiation unit and a direction of a second processing to be processed by the irradiation unit from a direction different from the direction of the first processing with respect to the processed surface to be generated by the first processing, calculates turning angles about the turning axes that changes the direction of the stage from the direction of the first processing to the direction of the second processing.

Lithographic apparatuses suitable for, and methodologies involving, complementary e-beam lithography (CEBL) are described. In an example, a blanker aperture array (BAA) for an e-beam tool includes a first column of openings along a first direction, each of the openings of the first column of openings having dog-eared corners. The BAA also includes a second column of openings along the first direction and staggered from the first column of openings, each of the openings of the second column of openings having dog-eared corners. The first and second columns of openings together form an array having a pitch in the first direction. A scan direction of the BAA is along a second direction, orthogonal to the first direction. The pitch of the array corresponds to half of a minimal pitch layout of a target pattern of lines for orientation parallel with the second direction.

Lithographic apparatuses suitable for, and methodologies involving, complementary e-beam lithography (CEBL) are described. In an example, a column for an e-beam direct write lithography tool includes a first blanker aperture array (BAA) including a staggered array of openings having a pitch along an array direction. The array direction is orthogonal to a scan direction. Each opening has a first dimension in the array direction. The column also includes a second BAA including a staggered array of openings having the pitch along the array direction. Each opening has a second dimension in the array direction, the second dimension greater than the first dimension.

A system and method for maskless direct write lithography are disclosed. The method includes receiving a plurality of pixels that represent an integrated circuit (IC) layout; identifying a first subset of the pixels that are suitable for a first compression method; and identifying a second subset of the pixels that are suitable for a second compression method. The method further includes compressing the first and second subset using the first and second compression method respectively, resulting in compressed data. The method further includes delivering the compressed data to a maskless direct writer for manufacturing a substrate. In embodiments, the first compression method uses a run-length encoding and the second compression method uses a dictionary-based encoding. Due to the hybrid compression method, the compressed data can be decompressed with a data rate expansion ratio sufficient for high-volume IC manufacturing.

According to one embodiment, a proximity effect correcting method includes acquiring drawing information for drawing a pattern on a substrate with irradiation of an electron beam. The method further includes acquiring surface profile information related to a surface profile of the substrate. The method further includes calculating an energy distribution of a backscattered beam to be produced by backscattering of the electron beam in the substrate on a basis of the acquired drawing information and surface profile information. The method further includes calculating a required energy amount of the electron beam on a basis of the calculated energy distribution.

An electron beam lithography system and an electron beam lithography process are disclosed herein for improving throughput. An exemplary method for increasing throughput achieved by an electron beam lithography system includes receiving an integrated circuit (IC) design layout that includes a target pattern, wherein the electron beam lithography system implements a first exposure dose to form the target pattern on a workpiece based on the IC design layout. The method further includes inserting a dummy pattern into the IC design layout to increase a pattern density of the IC design layout to greater than or equal to a threshold pattern density, thereby generating a modified IC design layout. The electron beam lithography system implements a second exposure dose that is less than the first exposure dose to form the target pattern on the workpiece based on the modified IC design layout.

A method of evaluating a region of a sample that includes a first sub-region and a second sub-region, adjacent to the first sub-region, the region comprising a plurality of sets of vertically-stacked double-layers extending through both the first and second sub-regions with a geometry or orientation of the vertically-stacked double layers in the first sub-region being different than a geometry or orientation of the vertically-stacked double layers in the second region resulting in the first sub-region having a first milling rate and the second sub-region having a second milling rate different than the first milling rate, the method including: milling the region of a sample by scanning a focused ion beam over the region a plurality of iterations in which, for each iteration, the focused ion beam is scanned over the first sub-region and the second sub-region generating secondary electrons and secondary ions from each of the first and second sub-regions; detecting, during the milling, at least one of the generated secondary electrons or the secondary ions; generating, in real-time, an endpoint detection signal from the at least one of detected secondary electrons or secondary ions, the endpoint detection signal including a fast oscillating signal having a first frequency and a slow oscillating signal having a second frequency, slower than the first frequency; analyzing the fast and slow oscillating signals to determine original first and second frequencies of the fast and slow oscillating signals; and estimating, in real-time, a depth of each of the first and second sub-regions based on the determined first and second frequencies.

An electron beam lithography system and an electron beam lithography process are disclosed herein for improving throughput. An exemplary method for increasing throughput achieved by an electron beam lithography system includes receiving an integrated circuit (IC) design layout that includes a target pattern, wherein the electron beam lithography system implements a first exposure dose to form the target pattern on a workpiece based on the IC design layout. The method further includes inserting a dummy pattern into the IC design layout to increase a pattern density of the IC design layout to greater than or equal to a threshold pattern density, thereby generating a modified IC design layout. The electron beam lithography system implements a second exposure dose that is less than the first exposure dose to form the target pattern on the workpiece based on the modified IC design layout.

According to one embodiment, a proximity effect correcting method includes acquiring drawing information for drawing a pattern on a substrate with irradiation of an electron beam. The method further includes acquiring surface profile information related to a surface profile of the substrate. The method further includes calculating an energy distribution of a backscattered beam to be produced by backscattering of the electron beam in the substrate on a basis of the acquired drawing information and surface profile information. The method further includes calculating a required energy amount of the electron beam on a basis of the calculated energy distribution.